Photovoltaic sensor facilities in a home environment

ABSTRACT

Photovoltaic cells, facilities, systems and methods, as well as related compositions, are disclosed. Embodiments involve providing a sensor in association with a photovoltaic facility to form a sensor-pv facility; and providing the sensor-pv facility in a kit adapted for purchase by a consumer to be deployed in a home environment.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation-in-part of, and claimspriority under U.S.C. §120 to, U.S. Ser. No. 10/258,708, filed Oct. 25,2002 [Q-04], which, in turn, claims priority under 35 U.S.C. §371 tointernational patent application serial number PCT/AT01/00129, filedApr. 27, 2001, which, in turn, claims priority to Austrian patentapplication serial number 734/2000, filed Apr. 27, 2000. The presentapplication is a continuation-in-part of, and claims priority underU.S.C. §120 to, U.S. Ser. No. 10/258,709, filed Oct. 25, 2002 [Q-05],which, in turn, claims priority under 35 U.S.C. §371 to internationalpatent application serial number PCT/AT01/00128, filed Apr. 27, 2001,which, in turn, claims priority to Austrian patent application serialnumber 735/2000, filed Apr. 27, 2000. The present application is acontinuation-in-part of, and claims priority under U.S.C. §120 to, U.S.Ser. No. 10/258,713, filed Oct. 25, 2002 [Q-03], which, in turn, claimspriority under 35 U.S.C. §371 to international patent application serialnumber PCT/AT01/00130, filed Apr. 27, 2001, which, in turn, claimspriority to Austrian patent application serial number 733/2000, filedApr. 27, 2000. The present application is a continuation-in-part of, andclaims priority under 35 U.S.C. §120 to, U.S. Ser. No. 10/351,607, filedJan. 24, 2003 [KON-002], which, in turn, is a continuation-in-part ofU.S. Ser. No. 10/057,394, filed Jan. 25, 2002, now U.S. Pat. No.6,706,963 [KON-001], and also claims the benefit under 35 U.S.C. §119 ofU.S. Ser. Nos. 60/351,691, filed Jan. 25, 2002 [KON-003PR], 60/353,138,filed Feb. 1, 2002 [KON-002PR], 60/368,832 filed Mar. 29, 2002[KON-004PR], and 60/400,289, filed Jul. 31, 2002 [KON-011PR]. Thepresent application is a continuation-in-part of, and claims priorityunder 35 U.S.C. §120 to, U.S. Ser. No. 10/350,913, filed Jan. 24, 2003[KON-003], which, in turn, is a continuation-in-part of U.S. Ser. No.10/057,394, filed Jan. 25, 2002, now U.S. Pat. No. 6,706,963 [KON-001],and also claims the benefit under 35 U.S.C. § 119 of U.S. Ser. Nos.60/351,691, filed Jan. 25, 2002 [KON-003PR], 60/368,832 filed Mar. 29,2002 [KON-004PR], and 60/400,289, filed Jul. 31, 2002 [KON-011PR]. Thepresent application is a continuation-in-part of, and claims priorityunder 35 U.S.C. §120 to, U.S. Ser. No. 10/350,912, filed Jan. 24, 2003[KON-004], which, in turn, is a continuation-in-part of U.S. Ser. No.10/057,394, filed Jan. 25, 2002, now U.S. Pat. No. 6,706,963 [KON-001],and also claims the benefit under 35 U.S.C. §119 of U.S. Ser. Nos.60/351,691, filed Jan. 25, 2002 [KON-003PR], 60/368,832 filed Mar. 29,2002 [KON-004PR], and 60/400,289, filed Jul. 31, 2002 [KON-011PR]. Thepresent application is a continuation-in-part of, and claims priorityunder 35 U.S.C. §126 to, U.S. Ser. No. 10/350,812, filed Jan. 24, 2003[KON-005], which, in turn, is a continuation-in-part of U.S. Ser. No.10/057,394, filed Jan. 25, 2002, now U.S. Pat. No. 6,706,963 [KON-001],and also claims the benefit under 35 U.S.C. §119 of U.S. Ser. Nos.60/351,691, filed Jan. 25, 2002 [KON-003PR], 60/368,832, filed Mar. 29,2002 [KON-004PR], 60/390,071, filed Jun. 20, 2002 [KON-006PR],60/396,173, filed Jul. 16, 2002 [KON-005PR], and 60/400,289, filed Jul.31, 2002 [KON-011PR]. The present application is a continuation-in-partof, and claims priority under 35 U.S.C. §120 to, U.S. Ser. No.10/350,800, filed Jan. 24, 2003 [KON-006], which, in turn, is acontinuation-in-part of U.S. Ser. No. 10/057,394, filed Jan. 25, 2002,now U.S. Pat. No. 6,706,963 [KON-001], and also claims the benefit under35 U.S.C. §119 of U.S. Ser. Nos. 60/390,071, filed Jun. 20, 2002[KON-006PR], and 60/400,289, filed Jul. 31, 2002 [KON-011PR]. Thepresent application is a continuation-in-part of, and claims priorityunder 35 U.S.C. §120 to, U.S. Ser. No. 10/351,298, filed Jan. 24, 2003[KON-007], which, in turn, is a continuation-in-part of U.S. Ser. No.10/057,394, filed Jan. 25, 2002, now U.S. Pat. No. 6,706,963 [KON-001],and also claims the benefit under 35 U.S.C. §119 of U.S. Ser. Nos.60/351,691, filed Jan. 25, 2002 [KON-003PR], 60/368,832, filed Mar. 29,2002 [KON-004PR], 60/400,289, filed Jul. 31, 2002 [KON-011PR], and60/427,642, filed Nov. 19, 2002 [KON-012PR]. The present application isa continuation-in-part of, and claims priority under 35 U.S.C. §120 to,U.S. Ser. No. 10/351,260, filed Jan. 24, 2003 [KON-008], which, in turn,is a continuation-in-part of U.S. Ser. No. 10/057,394, filed Jan. 25,2002, now U.S. Pat. No. 6,706,963 [KON-001], and also claims the benefitunder 35 U.S.C. § 119 of U.S. Ser. Nos. 60/351,691, filed Jan. 25, 2002[KON-003PR], 60/368,832, filed Mar. 29, 2002 [KON-004PR], and60/400,289, filed Jul. 31, 2002 [KON-011PR]. The present application isa continuation-in-part of, and claims priority under 35 U.S.C. §120 to,U.S. Ser. No. 10/351,249, filed Jan. 24, 2003 [KON-009], which claimsthe benefit under 35 U.S.C. § 119 of U.S. Ser. No. 60/400,289, filedJul. 31, 2002 [KON-011PR]. The present application is acontinuation-in-part of, and claims priority under 35 U.S.C. § 120 to,U.S. Ser. No. 10/350,919, filed Jan. 24, 2003 [KON-010], which, in turn,is a continuation-in-part of U.S. Ser. No. 10/057,394, filed Jan. 25,2002, now U.S. Pat. No. 6,706,963 [KON-001], and also claims the benefitunder 35 U.S.C. §119 of U.S. Ser. Nos. 60/351,691, filed Jan. 25, 2002[KON-003PR], 60/368,832, filed Mar. 29, 2002 [KON-004PR], and60/400,289, filed Jul. 31, 2002 [KON-011PR]. The present application isa continuation-in-part of, and claims priority under 35 U.S.C. §120 to,U.S. Ser. No. 10/351,264, filed Jan. 24, 2003 [KON-011], which claimsthe benefit under 35 U.S.C. §119 of U.S. Ser. Nos. 60/400,289, filedJul. 31, 2002 [KON-011PR], and 60/427,642, filed Nov. 19, 2002[KON-012PR]. The present application is a continuation-in-part of, andclaims priority under 35 U.S.C. §120 to, U.S. Ser. No. 10/351,265, filedJan. 24, 2003 [KON-012], which, in turn, is a continuation-in-part ofU.S. Ser. No. 10/057,394, filed Jan. 25, 2002, now U.S. Pat. No.6,706,963 [KON-001], and also claims the benefit under 35 U.S.C. § 119of U.S. Ser. Nos. 60/351,691, filed Jan. 25, 2002 [KON-003PR],60/368,832, filed Mar. 29, 2002 [KON-004PR], 60/427,642, filed Nov. 19,2002 [KON-012PR], and 60/400,289, filed Jul. 31, 2002 [KON-011PR]. Thepresent application is a continuation-in-part of, and claims priorityunder 35 U.S.C. §120 to, U.S. Ser. No. 10/351,251, filed Jan. 24, 2003[KON-013], which, in turn, is a continuation-in-part of U.S. Ser. No.10/057,394, filed Jan. 25, 2002, now U.S. Pat. No. 6,706,963 [KON-001],and also claims the benefit under 35 U.S.C. §119 of U.S. Ser. Nos.60/351,691, filed Jan. 25, 2002 [KON-003PR], 60/368,832, filed Mar. 29,2002 [KON-004PR], 60/427,642, filed Nov. 19, 2002 [KON-012PR], and60/400,289, filed Jul. 31, 2002 [KON-011PR]. The present application isa continuation-in-part of, and claims priority under 35 U.S.C. §120 to,U.S. Ser. No. 10/351,250, filed Jan. 24, 2003 [KON-014], which, in turn,is a continuation-in-part of U.S. Ser. No. 10/057,394, filed Jan. 25,2002, now U.S. Pat. No. 6,706,963 [KON-001], and also claims the benefitunder 35 U.S.C. §119 of U.S. Ser. Nos. 60/351,691, filed Jan. 25, 2002[KON-003PR], 60/368,832, filed Mar. 29, 2002 [KON-004PR], 60/427,642,filed Nov. 19, 2002 [KON-012PR], and 60/400,289, filed Jul. 31, 2002[KON-011PR]. The present application is a continuation-in-part of, andclaims priority under U.S.C. §120 to, U.S. Ser. No. 10/486,116, filedFeb. 6, 2004 [Q-01], which, in turn, claims priority under 35 U.S.C.§371 to international patent application serial number PCT/AT02/00166,filed May 31, 2002, which, in turn, claims priority to Austrian patentapplication serial number 1231/2001, filed Aug. 7, 2001. The presentapplication is a continuation-in-part of, and claims priority underU.S.C. §120 to, U.S. Ser. No. 10/494,560, filed May 4, 2004 [KON-025],which, in turn, claims priority under 35 U.S.C. §371 to internationalpatent application serial number PCT/SE02/02049, filed Nov. 8, 2002,which, in turn, claims priority to Swedish patent application serialnumber 0103740-7, filed Nov. 8, 2001. The present application is acontinuation-in-part of, and claims priority under U.S.C. §120 to, U.S.Ser. No. 10/498,484, filed Jun. 14, 2004 [SA-3], which, in turn, claimspriority under 35 U.S.C. §371 to international patent application serialnumber PCT/DE02/04563, filed Feb. 12, 2002, which, in turn, claimspriority to German patent application serial number 101 61 303.2, filedDec. 13, 2001. The present application is a continuation-in-part of, andclaims priority under U.S.C. § 120 to, U.S. Ser. No. 10/504,091, filedAug. 1, 2004 [SA-2], which, in turn, claims priority under 35 U.S.C.§371 to international patent application serial number PCT/DE03/00385,filed Feb. 10, 2003, which, in turn, claims priority to German patentapplication serial number 102 05 579.3, filed Feb. 12, 2002. The presentapplication is a continuation-in-part of, and claims priority underU.S.C. §120 to, U.S. Ser. No. 10/509,935, filed Oct. 1, 2004 [Q-02],which, in turn, claims priority under 35 U.S.C. §371 to internationalpatent application serial number PCT/AT03/00131, filed May 6, 2003,which, in turn, claims priority to Austrian patent application serialnumber 775/2002, filed May 22, 2002. The present application is acontinuation-in-part of, and claims priority under U.S.C. §120 to, U.S.Ser. No. 10/515,159, filed Nov. 19, 2004 [SA-7], which, in turn, claimsthe benefit under 35 U.S.C. §371 to international patent applicationserial number PCT/DE03/01867, filed Jun. 5, 2003, which, in turn, claimspriority to German patent application serial number 102 26 669.7, filedJun. 14, 2002. The present application is a continuation-in-part of, andclaims priority under 35 U.S.C. §120 to, U.S. Ser. No. 10/723,554, filedNov. 26, 2003 [KON-018], which, in turn, is a continuation-in-part of10/395,823, filed Mar. 24, 2003 [KON-015], which, in turn, claims thebenefit under 35 U.S.C. § 119 of U.S. Ser. Nos. 60/368,832, filed Mar.29, 2002, and 60/400,289, filed Jul. 31, 2002. The present applicationis a continuation-in-part of, and claims priority under U.S.C. § 120 to,U.S. Ser. No. 10/897,268, filed Jul. 22, 2004 [KON-016], which, in turn,claims the benefit under 35 U.S.C. § 119 of U.S. Ser. No. 60/495,302,filed Aug. 15, 2003. The present application is a continuation-in-partof, and claims priority under U.S.C. § 120 to, U.S. Ser. No. 11/000,276,filed Nov. 30, 2004 [KON-017], which, in turn, claims the benefit under35 U.S.C. §119 of U.S. Ser. No. 60/526,373, filed Dec. 1, 2003. Thepresent application is a continuation-in-part of, and claims priorityunder U.S.C. §120 to, U.S. Ser. No. 11/033,217, filed Jan. 10, 2005[KON-019], which, in turn, claims the benefit under 35 U.S.C. § 119 ofU.S. Ser. No. 60/546,818, filed Feb. 19, 2004. The present applicationis a continuation-in-part of, and claims priority under U.S.C. § 120 to,U.S. Ser. No. 10/522,862, filed Dec. 31, 2005 [SA-4], which, in turn,claims the benefit under 35 U.S.C. §371 to international patentapplication serial number PCT/DE03/02463, filed Jul. 22, 2003, which, inturn, claims priority to German patent application serial number 102 36464.8, filed Aug. 8, 2002.

The present application claims priority under 35 U.S.C. §119 to: U.S.Ser. No. 60/575,971, filed Jun. 1, 2004 [KON-020]; U.S. Ser. No.60/576,033, filed Jun. 2, 2004 [KON-021]; U.S. Ser. No. 60/589,423,filed Jul. 20, 2004 [KON-023]; U.S. Ser. No. 60/590,312, filed Jul. 22,2004 [KON-026]; U.S. Ser. No. 60/590,313, filed Jul. 22, 2004 [KON-027];60/637,844, filed Dec. 20, 2004 [KON-028]; U.S. Ser. No. 60/638,070,filed Dec. 21, 2004 [KON-02960/664,298, filed Mar. 22, 2005 [KON-024];60/663,985, filed Mar. 21, 2005 [KON-030]; 60/664,114, filed Mar. 21,2005 [KON-031]; and 60/664,336, filed Mar. 23, 2005 [KON-24B].

The contents of these applications are hereby incorporated by reference.

TECHNICAL FIELD

The invention relates to photovoltaic cells, systems and methods, aswell as related compositions.

BACKGROUND

Photovoltaic cells, sometimes called solar cells, can convert light,such as sunlight, into electrical energy.

One type of photovoltaic cell is commonly referred to as adye-sensitized solar cell (DSSC). As shown in FIG. 1, a DSSC 100 caninclude a charge carrier layer 140 (e.g., including an electrolyte, suchas an iodide/iodine solution) and a photoactive layer 145 disposedbetween electrically conductive layers 120 (e.g., an ITO layer or tinoxide layer) and 150 (e.g., an ITO layer or tin oxide layer).Photoactive layer 145 typically includes a semiconductor material, suchas TiO₂ particles, and a photosensitizing agent, such as a dye. Ingeneral, the photosensitizing agent is capable of absorbing photonswithin a wavelength range of operation (e.g., within the solarspectrum). DSSC 100 also includes a substrate 160 (e.g., a glass orpolymer substrate) and a substrate 110 (e.g., a glass or polymersubstrate). Electrically conductive layer 150 is disposed on an innersurface 162 of substrate 160, and electrically conductive layer 120 isdisposed on an inner surface 112 of substrate 110. DSSC 100 furtherincludes a catalyst 130 (e.g., formed of platinum), which can catalyze aredox reaction in charge carrier layer 140. Catalyst layer 130 istypically disposed on a surface 122 of electrically conductive layer120. Electrically conductive layers 120 and 150 are electricallyconnected across an external electrical load 170.

During operation, in response to illumination by radiation in the solarspectrum, DSSC 100 can undergo cycles of excitation, oxidation, andreduction that produce a flow of electrons across load 170. Incidentlight can excite photosensitizing agent molecules in photoactive layer145. The photoexcited photosensitizing agent molecules can then injectelectrons into the conduction band of the semiconductor in layer 145,which can leave the photosensitizing agent molecules oxidized. Theinjected electrons can flow through the semiconductor material, toelectrically conductive layer 150, then to external load 170. Afterflowing through external load 170, the electrons can flow to layer 120,then to layer 130 and subsequently to layer 140, where the electrons canreduce the electrolyte material in charge carrier layer 140 at catalystlayer 130. The reduced electrolyte can then reduce the oxidizedphotosensitizing agent molecules back to their neutral state. Theelectrolyte in layer 140 can act as a redox mediator to control the flowof electrons from layer 120 to layer 150. This cycle of excitation,oxidation, and reduction can be repeated to provide continuouselectrical energy to external load 170.

Another type of photovoltaic cell is commonly referred to a polymerphotovoltaic cell. As shown in FIG. 2, a polymer photovoltaic cell 200can include a first substrate 210 (e.g., a glass or polymer substrate),a first electrically conductive layer 220 (e.g., an ITO layer or tinoxide layer), a hole blocking layer 230 (e.g., a lithium fluoride ormetal oxide layer), a photoactive layer 240, a hole carrier layer 250(e.g., a polymer layer), a second electrically conductive layer 260(e.g., an ITO layer or tin oxide layer), and a second substrate 270(e.g., a glass or polymer substrate).

Light can interact with photoactive layer 240, which generally includesan electron donor material (e.g., a polymer) and an electron acceptormaterial (e.g., a fullerene). Electrons can be transferred from theelectron donor material to the electron acceptor material. The electronacceptor material in layer 240 can transmit the electrons through holeblocking layer 230 to electrically conductive layer 220. The electrondonor material in layer 240 can transfer holes through hole carrierlayer 250 to electrically conductive layer 260. First and secondelectrically conductive layers 220 and 260 are electrically connectedacross an external load 280 so that electrons pass from electricallyconductive layer 260 to electrically conductive layer 220.

SUMMARY

The invention relates to photovoltaic cells, facilities, systems andmethods, as well as related compositions. An aspect of the presentinvention relates to associating photovoltaics with sensors.

In embodiments a photovoltaic sensor system may be provided comprisingat least one photovoltaic facility and at least one electrical sensor.The photovoltaic facility may provide energy for the electrical sensor.In other embodiments, a method of a photovoltaic sensor system may beprovided comprising providing at least one photovoltaic facility andusing at least one electric interference sensor. The photovoltaicfacility may provide energy for the electric interference sensor.

In other embodiments, a method of a photovoltaic sensor system may beprovided comprising providing at least one photovoltaic facility andusing at least one sensor. The sensor may be at least one of a voltagesensor, a current sensor, a resistance sensor, a thermistor sensor, anelectrostatic sensor, a frequency sensor, a temperature sensor, a heatsensor, a thermostat, a thermometer, a light sensor, a differentiallight sensor, an opacity sensor, a scattering light sensor, adiffractional sensor, a refraction sensor, a reflection sensor, apolarization sensor, a phase sensor, a florescence sensor, aphosphorescence sensor, an optical activity sensor, an optical sensorarray, an imaging sensor, a micro mirror array, a pixel array, a micropixel array, a rotation sensor, a velocity sensor, an accelerometer, aninclinometer and a momentum sensor. The photovoltaic facility mayprovide energy for the sensor.

Also disclosed is a method of providing printed material which maycomprise taking a material with printed content and associating aphotovoltaic facility with the printed material. The photovoltaicfacility may provide energy for an item that is associated with thecontent. The item may be a lighted display or an animated display. Thecontent may include an advertisement. The material may be at least oneof a magazine or a book.

Also disclosed is a method of making a beverage container which maycomprise taking a beverage container, associating a photovoltaicfacility with the beverage container and associating a display with thebeverage container and the photovoltaic facility. The photovoltaicfacility may provide power to the display. The display may include anadvertisement. The method may further comprise providing a thermosensorand a processor configured to detect and display an indication of atemperature of a liquid in the beverage container.

In embodiments, a method of providing a packaging may comprise providinga packaging for an electronic device and associating a photovoltaicfacility with the packaging. The electronic device may include an energysource and at least one electronic try me feature powered by the energysource. The photovoltaic facility may convert ambient light intoelectrical energy to recharge the energy source. The electronic devicemay include one or more of a game, a toy, an instrument or a personalelectronic device.

Also disclosed is a method for fabricating an RFID device which maycomprise providing an RFID device including an energy source andprinting a photovoltaic facility on an exterior surface of the RFIDdevice. The photovoltaic facility may provide electrical energy torecharge the energy source in response to incident light. In anotherembodiment, a portable power supply may comprise a case, one or morephotovoltaic facilities stored within the case and adapted to bedeployed from the case to provide electrical energy and a powerconversion system within the case adapted to receive electrical energyfrom the one or more photovoltaic facilities and provide a convertedelectrical output. The portable power supply may further comprise aplurality of outputs from the power conversion system conforming to aplurality of industrial standards for electrical supply. The portablepower supply may further comprise an energy storage device. The portablepower supply may further comprise a control circuitry to provide userfeedback. The portable power supply may further comprise a control panelfor selecting a type of electrical output.

In embodiments, a device may comprise a case adapted to hold a portableelectronic device, one or more photovoltaic facilities adapted to bedeployed from the case and a power conversion system within the case.The power conversion system may be configured to receive electricalenergy from the photovoltaic facilities and may output electrical energyin a form suitable for use by the portable electronic device. Theportable electronic device may include a portable computer. The devicemay further comprise one or more photovoltaic cells integrated into anexterior surface of the case. The device may further comprise one ormore photovoltaic cells integrated into an exterior surface of theportable electronic device.

In embodiments, a method for monitoring perishable goods may compriseproviding a monitoring system for perishable goods, associating themonitoring system with one or more packages of the perishable goods,disposing a photovoltaic facility on an exterior of the one or morepackages, powering the monitoring system with electricity from thephotovoltaic facility and displaying a status of the perishable goods.The exterior may include an exterior of a container holding one or morepackages. The monitoring system may include one or more sensors. Themonitoring system may include a radio frequency communications system.

A cooling device may comprise an insulated container, an electriccooling device for cooling an interior of the insulated container and aphotovoltaic facility that provides electrical energy to the electriccooling device in response to incident light. The photovoltaic facilitymay fold into a compact form for storage. The photovoltaic facility mayroll into a compact form for storage. The cooling device may furthercomprise a controller for managing the operation of the electric coolingdevice.

In embodiments, a method for agricultural monitoring may compriseproviding a monitoring system including one or more sensors foragricultural monitoring, placing the monitoring system in anagricultural environment and powering the monitoring system with acollapsible photovoltaic facility. The method may further comprisedisplaying a status of the agricultural environment on a displayassociated with the monitoring system. The method may further comprisedisposing a plurality of monitoring systems in the agriculturalenvironment to form an agricultural monitoring network.

In embodiments, a device may be provided comprising a shade formed ofone or more photovoltaic facilities and a power system to captureelectrical energy generated when the shade is exposed to sunlight. Theshade may be used to shade tobacco on a tobacco farm. The shade maycomprise a tent.

A device may be provided comprising a covering for a sports venue formedof one or more photovoltaic facilities and a power system to captureelectrical energy generated when the covering is exposed to sunlight.The sports venue may be one of a stadium, a dome or an arena.

In embodiments, a method may be provided for generating electricitycomprising providing a mound of material sensitive to an environmentalcondition, covering the mound with one or more photovoltaic facilitiesto protect the mound from the environmental condition and capturingelectrical energy generated when the covering is exposed to sunlight.The mound of material may include landfill material or salt. Theenvironmental condition may include sunlight or rain.

In embodiments, a method may be provided for providing a photovoltaicplant, comprising providing a photovoltaic leaf and providing aconductive core. The photovoltaic leaf may be associated with thephotovoltaic core. A method for measuring flex may also be providedcomprising comparing an electrical output with a reference electricaloutput. The electrical output may be powered by a photovoltaic facilityand the reference electrical output may be powered by a photovoltaicfacility. In other embodiments, the method for determining flex maycomprise observing an electrical output. The electrical output may bebinary with both a logical transition associated with a flexiblefacility being flexed beyond a first degree of flex and a logicaltransition associated with the flexible facility being relaxed beyond asecond degree of flex. The electrical output may be powered by aphotovoltaic facility.

A method of sensing may be provided comprising generating a sensoroutput. The sensor output may be associated with the operation of ananoscale cantilever sensor. The nanoscale cantilever sensor may bepowered by a photovoltaic facility. A method of generating power mayalso be provided which may comprise providing a self-orienting,omni-directional photovoltaic facility. The self-orientation of thephotovoltaic facility may be with respect to the surface of a planet.

In embodiments, a method of providing power to a sensor may be providedwhich may comprise associating a sensor with a photovoltaic fabric. Amethod for providing a solar powered sensor network may also be providedwhich may comprise associating a photovoltaic facility with a sensornode. The sensor node may comprise a communication facility and may beoperatively coupled to another like sensor node via the communicationfacility. The sensor node may be powered by the photovoltaic facility.

A method for providing a warning facility is also provided which maycomprise associating a photovoltaic facility with an accumulator anddisposing the photovoltaic facility on an item worn by a person. Amethod of providing a photovoltaic smoke detector system may compriseproviding at least one photovoltaic facility and associating at leastone smoke sensor with the at least one photovoltaic facility. The sensormay be a smoke detector in a home, a smoke detector in a non-homeenvironment or a smoke detector in an industrial environment. The atleast one photovoltaic facility and the at least one smoke sensor maycomprise a mobile unit.

In embodiments, a method of providing a photovoltaic fire detectorsystem may be provided comprising providing at least one photovoltaicfacility and associating at least one fire sensor with the at least onephotovoltaic facility. The sensor may be a fire detector in a home, afire detector in a non-home environment or a fire detector in anindustrial environment. The at least one photovoltaic facility and theat least one fire sensor may comprise a mobile unit. A method ofproviding a photovoltaic heat detector system may comprise providing atleast one photovoltaic facility and associating at least one heat sensorwith the at least one photovoltaic facility. The sensor may be a heatdetector in a home, a heat detector in a non-home environment or a heatdetector in an industrial environment. The at least one photovoltaicfacility and the at least one heat sensor may comprise a mobile unit.

A method of providing a hybrid detection system may comprise providingat least one photovoltaic facility and associating at least one sensorwith at least two of the following functionalities: smoke sensor, firesensor and heat sensor. A method of providing a photovoltaic vapordetection system may comprise providing at least one photovoltaicfacility and associating at least one vapor sensor with the at least onephotovoltaic facility. The vapor sensor may detect certaincharacteristics of the vapor such as composition, moisture level,pressure, temperature, direction, speed, dispersion, density,reactivity, inertness, acidity, concentration and source.

In embodiments, a method of providing a photovoltaic gas detectionsystem may be provided which may comprise providing at least onephotovoltaic facility and associating at least one gas sensor with theat least one photovoltaic facility. The gas sensor may detect certaincharacteristics of the gas such as composition, moisture level,pressure, temperature, direction, speed, dispersion, density,reactivity, inertness, acidity, concentration and source.

A method of providing a signal sensor may comprise providing at leastone photovoltaic facility and associating at least one signal sensorwith the at least one photovoltaic facility. The signal sensor may senseany one or more of the following signals: a signal from another sensor,a cable signal, a phone signal, a satellite signal, a telecommunicationssignal, a voice signal, an analog signal, a digital signal, anelectrical signal and a mechanical signal.

A method of providing a photovoltaic gas detection system may compriseproviding at least one photovoltaic facility and associating at leastone wireless signal sensor with the at least one photovoltaic facility.The wireless sensor may detect at least one of the following signals:IEEE 802.11, jNetX, Bluetooth, Blackberry or TracerPlus. A cellularsignal sensor may be substituted for the wireless signal sensor. A Wi-Fisignal sensor may be substituted for the wireless signal sensor. Aninternet signal sensor may be substituted for the wireless signalsensor. The internet sensor may detect internet protocol informationsuch as bandwidth, encryption type, security information or the networkbeing accessed.

In other embodiments, a method of providing a photovoltaic gas detectionsystem may comprise providing at least one photovoltaic facility andassociating at least one touch signal sensor with the at least onephotovoltaic facility. The touch sensor may detect if an object contactsanother object. The method may result in activation and/or deactivationof a device. A method of providing a photovoltaic gas detection systemmay comprise providing at least one photovoltaic facility andassociating at least one contact signal sensor with the at least onephotovoltaic facility. The contact sensor may detect if an objectcontacts another object. The method may be used for security.

A method of providing a photovoltaic gas detection system may compriseproviding at least one photovoltaic facility and associating at leastone viscosity sensor with the at least one photovoltaic facility. Theviscosity sensor may measure a fluid. A method of providing aphotovoltaic gas detection system may also comprising providing at leastone photovoltaic facility and associating at least one position sensorwith the at least one photovoltaic facility. The position sensor maymeasure magnetic fields. The position sensor may measure a GPS signal.

A method of providing a photovoltaic gas detection system may comprisingproviding at least one photovoltaic facility and associating at leastone height sensor with the at least one photovoltaic facility. Theheight sensor may measure height in relation to a reference point. Themethod of providing a photovoltaic gas detection system may alsocomprise providing at least one photovoltaic facility and associating atleast one ray sensor with the at least one photovoltaic facility. Theray sensor may be for detecting gamma rays. The ray sensor may be fordetecting X-rays. The method of providing a photovoltaic gas detectionsystem may also comprising providing at least one photovoltaic facilityand associating at least one microwave sensor with the at least onephotovoltaic facility. The microwave sensor may be for object detection.

Embodiments of the present invention relate to systems and methods ofproviding flexible photovoltaic facilities. The systems and methods mayinvolve providing a first photovoltaic cell; providing a secondphotovoltaic cell; and electrically and mechanically associating thefirst and second photovoltaic cells; wherein the association provides amechanically flexible photovoltaic facility, forming a flexiblephotovoltaic facility. In embodiments the flexible photovoltaic facilityis foldable. In embodiments the flexible photovoltaic facility isbendable. In embodiments the flexible photovoltaic facility is adaptedto be mounted on a flexible surface. In embodiments the flexiblephotovoltaic facility is folded and provided in a kit. In embodimentsthe flexible photovoltaic facility is directly deployable from the kit.In embodiments the deployment involves fully expanding the cells. Inembodiments at least one of the photovoltaic cells is a flexible cell.In embodiments the first photovoltaic cell comprises a dye-sensitizedsolar cell. In embodiments the dye-sensitized solar cell furthercomprises dye. In embodiments the dye is formed into a pattern. Inembodiments the first photovoltaic cell includes a semiconductormaterial in the form of nanoparticles. In embodiments the firstphotovoltaic cell includes an electrically conductive layer. Inembodiments the electrically conductive layer is transparent. Inembodiments the electrically conductive layer is semi-transparent. Inembodiments the electrically conductive material is translucent. Inembodiments the electrically conductive material is opaque. Inembodiments the electrically conductive material contains adiscontinuity. In embodiments the electrically conductive material formsa mesh. In embodiments the first photovoltaic cell is formed on aroll-to-roll process. In embodiments the cell is slit. In embodimentsthe first photovoltaic cell comprises a polymer photovoltaic cell. Inembodiments the methods and systems further comprise powering a sensorwith the flexible photovoltaic facility. In embodiments the sensorfacility includes a network. In embodiments the sensor facility includesa processor. In embodiments the sensor facility includes memory. Inembodiments the sensor includes a transmitter. In embodiments the sensorfacility includes a receiver. In embodiments the sensor facilitycomprises a MEMS sensor facility. In embodiments the sensor facilitycomprises an electrical sensor facility. In embodiments the sensorfacility comprises a mechanical sensor facility. In embodiments thesensor facility comprises a chemical sensor facility. In embodiments thesensor facility comprises an optical sensor facility.

An aspect of the present invention relates to systems and methods fordeploying sensor photovoltaic facilities in a home environment. Inembodiments, the methods and systems involve providing a sensor inassociation with a photovoltaic facility to form a sensor-pv facility;and providing the sensor-pv facility in a kit adapted for purchase by aconsumer to be deployed in a home environment. The systems and methodsmay involve providing an energy storage facility for storing energygenerated by the photovoltaic facility. The systems and methods mayinvolve providing a feedback loop from the sensor to control thesensor-pv facility. In embodiments, the sensor is a smoke detector, firedetector, a hazard detector, a hazardous waste detector, a gas detector,a mechanical sensor, an electrical sensor, a biological sensor, achemical sensor, an optical sensor, an ozone sensor, a carbon monoxidesensor, is a lead sensor, an asbestos sensor, a mold sensor, bacteriasensor, a temperature sensor, or other sensor. In embodiments thephotovoltaic facility is flexible. The photovoltaic facility mayfoldable, rotatable, or other flexible format. In embodiments, thephotovoltaic facility may be a dye-sensitized solar cell. Thedye-sensitized solar cell may include dye. The dye may be formed into apattern. In embodiments, the photovoltaic facility includes asemiconductor material in the form of nanoparticles. In embodiments, thephotovoltaic facility includes an electrically conductive layer. Theelectrically conductive layer may be transparent. The electricallyconductive layer may be semi-transparent. The electrically conductivematerial may be translucent. The electrically conductive material may beopaque. The electrically conductive material may contain adiscontinuity. The electrically conductive material may form a mesh. Thephotovoltaic facility may be formed on a roll-to-roll process. The cellmay be slit. In embodiments, the photovoltaic facility comprises apolymer photovoltaic facility. In embodiments, the methods and systemsmay also involve powering the sensor with the photovoltaic facility. Thesensor facility may include a network. The sensor facility may include aprocessor, memory, a transmitter, a receiver, or other active and orpassive circuitry. In embodiments, the sensor facility may be a MEMSsensor facility.

An aspect of the present invention relates to systems and methods foradapting a photovoltaic facility for a home environment. In embodiments,the methods and systems may involve providing a sensor in associationwith a photovoltaic facility to form a sensor-pv facility; and adaptingthe sensor-pv facility for a home environment; wherein the photovoltaicfacility is adapted to provide energy for the sensor. The methods andsystems may also involve providing an energy storage facility forstoring energy generated by the photovoltaic facility. The methods andsystems may also involve providing a feedback loop from the sensor tocontrol the sensor-pv facility. The systems and methods may involveproviding an energy storage facility for storing energy generated by thephotovoltaic facility. The systems and methods may involve providing afeedback loop from the sensor to control the sensor-pv facility. Inembodiments, the sensor is a smoke detector, fire detector, a hazarddetector, a hazardous waste detector, a gas detector, a mechanicalsensor, an electrical sensor, a biological sensor, a chemical sensor, anoptical sensor, an ozone sensor, a carbon monoxide sensor, is a leadsensor, an asbestos sensor, a mold sensor, bacteria sensor, atemperature sensor, or other sensor. In embodiments the photovoltaicfacility is flexible. The photovoltaic facility may foldable, rotatable,or other flexible format. In embodiments, the photovoltaic facility maybe a dye-sensitized solar cell. The dye-sensitized solar cell mayinclude dye. The dye may be formed into a pattern. In embodiments, thephotovoltaic facility includes a semiconductor material in the form ofnanoparticles. In embodiments, the photovoltaic facility includes anelectrically conductive layer. The electrically conductive layer may betransparent. The electrically conductive layer may be semi-transparent.The electrically conductive material may be translucent. Theelectrically conductive material may be opaque. The electricallyconductive material may contain a discontinuity. The electricallyconductive material may form a mesh. The photovoltaic facility may beformed on a roll-to-roll process. The cell may be slit. In embodiments,the photovoltaic facility comprises a polymer photovoltaic facility. Inembodiments, the methods and systems may also involve powering thesensor with the photovoltaic facility. The sensor facility may include anetwork. The sensor facility may include a processor, memory, atransmitter, a receiver, or other active and or passive circuitry. Inembodiments, the sensor facility may be a MEMS sensor facility. Featuresand advantages of the invention are in the description, drawings andclaims.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a cross-sectional view of an embodiment of a DSSC.

FIG. 2 is a cross-sectional view of an embodiment of a polymerphotovoltaic cell.

FIG. 3 is a cross-sectional view of an embodiment of a DSSC.

FIG. 4 illustrates a method of making a DSSC.

FIG. 5 is a schematic view of a module containing multiple photovoltaiccells.

FIG. 6 is a schematic view of a module containing multiple photovoltaiccells.

FIG. 7 is a cross-sectional view of an embodiment of a polymerphotovoltaic cell.

FIG. 8 is intentionally left blank.

FIG. 9 is intentionally left blank.

FIG. 10 is intentionally left blank.

FIG. 11 is intentionally left blank.

FIG. 12 is intentionally left blank.

FIG. 13 is intentionally left blank.

FIG. 14 is intentionally left blank.

FIG. 15 illustrates a photovoltaic sensor facility according to theprinciples of the present invention.

FIG. 16 illustrates a photovoltaic sensor facility in the presence ofsunlight according to the principles of the present invention.

FIG. 17 illustrates a photovoltaic sensor facility in the presence ofartificial light according to the principles of the present invention.

FIG. 18 illustrates a photovoltaic sensor facility including aphotovoltaic facility, a sensing facility, and an energy storagefacility according to the principles of the present invention.

FIG. 19 illustrates a photovoltaic sensor facility including aphotovoltaic facility, a sensing facility, and an energy filteringfacility according to the principles of the present invention.

FIG. 20 illustrates a photovoltaic sensor facility including aphotovoltaic facility, a sensing facility, and an energy regulationfacility according to the principles of the present invention.

FIG. 21 illustrates a photovoltaic sensor facility including aphotovoltaic facility, a sensing facility, an energy storage facility,and a recharging facility according to the principles of the presentinvention.

FIG. 22 illustrates a photovoltaic sensor facility including aphotovoltaic facility, a sensing facility, a processing facility, areceiving facility, a transmitting facility, and a memory facilityaccording to the principles of the present invention.

FIG. 23 illustrates a photovoltaic sensor facility including aphotovoltaic facility, a sensing facility, and an MEMS facilityaccording to the principles of the present invention.

FIG. 24 illustrates a photovoltaic sensor facility network according tothe principles of the present invention.

FIG. 25 illustrates a photovoltaic sensor facility network according tothe principles of the present invention.

FIG. 26 illustrates a photovoltaic sensor facility network according tothe principles of the present invention.

FIG. 27 illustrates a photovoltaic sensor facility network according tothe principles of the present invention.

FIG. 28 illustrates a photovoltaic sensor facility peer-to-peer networkaccording to the principles of the present invention.

FIG. 29 illustrates a photovoltaic sensor facility network wherein thecommunication between devices involves the internet according to theprinciples of the present invention.

FIG. 30 illustrates a photovoltaic sensor facility array incommunication with a network according to the principles of the presentinvention.

FIG. 31 illustrates several photovoltaic sensor facilities arranged on asensor network wherein the network of sensors is in communication with acomputer network according to the principles of the present invention.

FIGS. 32 A, B, C, and D illustrate several variable photovoltaicstructures according to the principles of the present invention.

FIG. 33 illustrates a variable photovoltaic structure wherein thevariable photovoltaic structure includes multiple photovoltaic segmentsconnected through electrical segments which can rotate or be rotatedaccording to the principles of the present invention.

FIG. 34 illustrates another variable photovoltaic structure wherein thevariable photovoltaic structure includes multiple photovoltaic segmentsconnected through foldable electrical segments according to theprinciples of the present invention.

FIG. 35 illustrates another variable photovoltaic structure wherein thevariable photovoltaic structure includes multiple photovoltaic segmentsconnected through foldable electrical segments according to theprinciples of the present invention.

FIG. 36 illustrates several variable photovoltaic structures accordingto the principles of the present invention.

FIG. 37 illustrates a variable photovoltaic structure with eightfoldable segments according to the principles of the present invention.

FIG. 38 illustrates several variable photovoltaic structures accordingto the principles of the present invention according to the principlesof the present invention.

FIG. 39 illustrates a variable photovoltaic structure adapted to senselight and position itself in relation to the light in accordance withthe principles of the present invention according to the principles ofthe present invention.

FIG. 40 illustrates a flexible photovoltaic facility in association witha sensor facility according to the principles of the present invention.

FIG. 41 illustrates an electrical sensor may detect the presence ofelectrical inputs such as voltage or current according to the principlesof the present invention.

FIG. 42 shows an electrical interference sensor may detect the presenceof electrical power according to the principles of the presentinvention.

FIG. 43 shows an automobile voltage sensor associated with aphotovoltaic cell(s) according to the principles of the presentinvention.

FIG. 44 illustrates a current sensor in association with a photovoltaiccell according to the principles of the present invention.

FIG. 45 shows a resistance sensor in association with a photovoltaiccell according to the principles of the present invention.

FIG. 46 illustrates a thermistor sensor in association with aphotovoltaic cell according to the principles of the present invention.

FIG. 47 shows an electrostatic sensor in association with a photovoltaiccell according to the principles of the present invention.

FIG. 48 shows a frequency sensor in association with a photovoltaic cellaccording to the principles of the present invention.

FIG. 49 illustrates a temperature sensor in association with aphotovoltaic cell according to the principles of the present invention.

FIG. 50 shows a photovoltaic powered heat sensor according to theprinciples of the present invention.

FIG. 51 illustrates a photovoltaic powered thermostat according to theprinciples of the present invention.

FIG. 52 shows a photovoltaic powered thermometer according to theprinciples of the present invention.

FIG. 53 shows a photovoltaic powered light sensor according to theprinciples of the present invention.

FIG. 54 shows a photovoltaic powered differential light sensor accordingto the principles of the present invention.

FIG. 55 shows a photovoltaic powered opacity sensor according to theprinciples of the present invention.

FIG. 56 shows a photovoltaic powered scattering light sensor accordingto the principles of the present invention.

FIG. 57 shows a photovoltaic powered diffractional sensor according tothe principles of the present invention.

FIG. 58 shows a photovoltaic powered refraction sensor according to theprinciples of the present invention.

FIG. 59 shows a photovoltaic reflection sensor according to theprinciples of the present invention.

FIG. 60 shows a photovoltaic polarization sensor according to theprinciples of the present invention.

FIG. 61 shows a photovoltaic phase sensor according to the principles ofthe present invention.

FIG. 62 shows a photovoltaic florescence sensor according to theprinciples of the present invention.

FIG. 63 shows a photovoltaic phosphorescence sensor according to theprinciples of the present invention.

FIG. 64 shows a photovoltaic optical activity sensor according to theprinciples of the present invention.

FIG. 65 shows a photovoltaic optical sensory array according to theprinciples of the present invention.

FIG. 66 shows a photovoltaic imaging sensor according to the principlesof the present invention.

FIG. 67 shows a photovoltaic micro mirror array according to theprinciples of the present invention.

FIG. 68 shows photovoltaic pixel array according to the principles ofthe present invention.

FIG. 69 shows a photovoltaic rotation sensor according to the principlesof the present invention.

FIG. 70 shows a photovoltaic velocity sensor according to the principlesof the present invention.

FIG. 71 shows a photovoltaic accelerometer according to the principlesof the present invention.

FIG. 72 shows a photovoltaic inclinometer according to the principles ofthe present invention.

FIG. 73 shows a photovoltaic momentum sensor according to the principlesof the present invention.

FIG. 74 is intentionally left blank.

FIG. 75 is intentionally left blank.

FIG. 76 is intentionally left blank.

FIG. 77 is intentionally left blank.

FIG. 78 is intentionally left blank.

FIG. 79 is intentionally left blank.

FIG. 80 is intentionally left blank.

FIG. 81 is intentionally left blank.

FIG. 82 is intentionally left blank.

FIG. 83 shows a photovoltaic facility associated with printed contentaccording to the principles of the present invention.

FIG. 84 shows a photovoltaic facility associated with a beveragecontainer according to the principles of the present invention.

FIG. 85 shows a photovoltaic facility incorporated into a “try me”feature of a packaged electrical device according to the principles ofthe present invention.

FIG. 86 shows a radio frequency identification (RFID) device printedwith a photovoltaic facility according to the principles of the presentinvention.

FIG. 87 shows a portable power source using one or more photovoltaicfacilities according to the principles of the present invention.

FIG. 88 shows a portable power supply for a computer according to theprinciples of the present invention.

FIG. 89 shows a photovoltaic facility in a perishable goods monitoringsystem according to the principles of the present invention.

FIG. 89A shows a photovoltaic facility integrated into a portable cooleraccording to the principles of the present invention.

FIG. 90 shows an agricultural or farm monitoring system using aphotovoltaic facility according to the principles of the presentinvention.

FIG. 91 shows a power supply system for a sports venue using aphotovoltaic facility according to the principles of the presentinvention.

FIG. 92 shows a power supply system for an outdoor working environmentusing a photovoltaic facility according to the principles of the presentinvention.

FIG. 93 shows a power supply system integrated with an outdoor coveringmaterial according to the principles of the present invention.

FIG. 94 shows a photovoltaic associated a natural or stylized appearanceof a leaf of a plant, forming a photovoltaic leaf according to theprinciples of the present invention.

FIG. 95 shows a photovoltaic facility disposed on a flexible facilityaccording to the principles of the present invention.

FIG. 96 shows a photovoltaic a nanoscale cantilever sensor according tothe principles of the present invention.

FIG. 97 shows a photovoltaic facility adapted for power generationprovided many inclinations of the sun according to the principles of thepresent invention.

FIG. 98 shows a photovoltaic fiber woven into a fabric according to theprinciples of the present invention.

FIG. 99 shows a photovoltaic facility associated with a sensor nodeaccording to the principles of the present invention.

FIG. 100 shows a photovoltaic facility associated with an accumulatoraccording to the principles of the present invention.

FIG. 101 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 102 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 103 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 104 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 105 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 106 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 107 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 108 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 109 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 110 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 111 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention.

FIG. 112 illustrates a photovoltaic sensor facility in a homeenvironment according to the principles of the present invention.

FIG. 113 illustrates a photovoltaic sensor facility in a governmentenvironment according to the principles of the present invention.

FIG. 114 illustrates a photovoltaic sensor facility in a officeenvironment according to the principles of the present invention.

FIG. 115 illustrates a photovoltaic sensor facility in a hospitalenvironment according to the principles of the present invention.

FIG. 116 illustrates a photovoltaic sensor facility in a industrialenvironment according to the principles of the present invention.

FIG. 117 illustrates a photovoltaic sensor facility in a storageenvironment according to the principles of the present invention.

FIG. 118 illustrates a photovoltaic sensor facility in a hazardreclamation environment according to the principles of the presentinvention.

FIG. 119 illustrates a photovoltaic sensor facility in a garageenvironment according to the principles of the present invention.

FIG. 120 illustrates a photovoltaic sensor facility in a stationenvironment according to the principles of the present invention.

DETAILED DESCRIPTION

FIG. 3 is a cross-sectional view of a DSSC 300 including substrates 310and 370, electrically conductive layers 320 and 360, a catalyst layer330, a charge carrier layer 340, and a photoactive layer 350.

Photoactive layer 350 generally includes one or more dyes and asemiconductor material associated with the dye.

Examples of dyes include black dyes (e.g.,tris(isothiocyanato)-ruthenium(II)-2,2′:6′,2″-terpyridine-4,4′,4″-tricarboxylic acid,tris-tetrabutylammonium salt), orange dyes (e.g.,tris(2,2′-bipyridyl-4,4′-dicarboxylato) ruthenium (II) dichloride,purple dyes (e.g.,cis-bis(isothiocyanato)bis-(2,2′-bipyridyl-4,4′-dicarboxylato)-ruthenium(II)), red dyes (e.g., an eosin), green dyes (e.g., a merocyanine) andblue dyes (e.g., a cyanine). Examples of additional dyes includeanthocyanines, porphyrins, phthalocyanines, squarates, and certainmetal-containing dyes.

In some embodiments, photoactive layer 350 can include multipledifferent dyes that form a pattern. Examples of patterns includecamouflage patterns, roof tile patterns and shingle patterns. In someembodiments, the pattern can define the pattern of the housing aportable electronic device (e.g., a laptop computer, a cell phone). Incertain embodiments, the pattern provided by the photovoltaic cell candefine the pattern on the body of an automobile. Patterned photovoltaiccells are disclosed, for example, in co-pending and commonly owned U.S.Ser. No. 60/638,070, filed Dec. 21, 2004 [KON-029], which is herebyincorporated by reference.

Examples of semiconductor materials include materials having the formulaM_(x)O_(y), where M may be, for example, titanium, zirconium, tungsten,niobium, lanthanum, tantalum, terbium, or tin and x and y are integersgreater than zero. Other suitable materials include sulfides, selenides,tellurides, and oxides of titanium, zirconium, tungsten, niobium,lanthanum, tantalum, terbium, tin, or combinations thereof. For example,TiO₂, SrTiO₃, CaTiO₃, ZrO₂, WO₃, La₂O₃, Nb₂O₅, SnO₂, sodium titanate,cadmium selenide (CdSe), cadmium sulphides, and potassium niobate may besuitable materials.

Typically, the semiconductor material contained within layer 350 is inthe form of nanoparticles. In some embodiments, the nanoparticles havean average size between about two nm and about 100 nm (e.g., betweenabout 10 nm and 40 nm, such as about 20 nm). Examples of nanoparticlesemiconductor materials are disclosed, for example, in co-pending andcommonly owned U.S. Ser. No. 10/351,249 [KON-009], which is herebyincorporated by reference.

The nanoparticles can be interconnected, for example, by hightemperature sintering, or by a reactive linking agent.

In certain embodiments, the linking agent can be a non-polymericcompound. The linking agent can exhibit similar electronic conductivityas the semiconductor particles. For example, for TiO₂ particles, theagent can include Ti—O bonds, such as those present in titaniumalkoxides. Without wishing to be bound by theory, it is believed thattitanium tetraalkoxide particles can react with each other, with TiO₂particles, and with a conductive coating on a substrate, to formtitanium oxide bridges that connect the particles with each other andwith the conductive coating (not shown). As a result, the cross-linkingagent enhances the stability and integrity of the semiconductor layer.The cross-linking agent can include, for example, an organometallicspecies such as a metal alkoxide, a metal acetate, or a metal halide. Insome embodiments, the cross-linking agent can include a different metalthan the metal in the semiconductor. In an exemplary cross-linking step,a cross-linking agent solution is prepared by mixing a sol-gel precursoragent, e.g., a titanium tetra-alkoxide such as titanium tetrabutoxide,with a solvent, such as ethanol, propanol, butanol, or higher primary,secondary, or tertiary alcohols, in a weight ratio of 0-100%, e.g.,about 5 to about 25%, or about 20%. Generally, the solvent can be anymaterial that is stable with respect to the precursor agent, e.g., doesnot react with the agent to form metal oxides (e.g. TiO₂). The solventpreferably is substantially free of water, which can cause precipitationof TiO₂. Such linking agents are disclosed, for example, in publishedU.S. Patent Application 2003-0056821 [UMASS application], which ishereby incorporated by reference.

In some embodiments, a linking agent can be a polymeric linking agent,such as poly(n-butyl titanate. Examples of polymeric linking agents aredisclosed, for example, in co-pending and commonly owned U.S. Ser. No.10/350,913 [KON-003], which is hereby incorporated by reference.

Linking agents can allow for the fabrication of an interconnectednanoparticle layer at relatively low temperatures (e.g., less than about300° C.) and in some embodiments at room temperature. The relatively lowtemperature interconnection process may be amenable to continuous (e.g.,roll-to-roll) manufacturing processes using polymer substrates.

The interconnected nanoparticles are generally photosensitized by thedye(s). The dyes facilitates conversion of incident light intoelectricity to produce the desired photovoltaic effect. It is believedthat a dye absorbs incident light resulting in the excitation ofelectrons in the dye. The energy of the excited electrons is thentransferred from the excitation levels of the dye into a conduction bandof the interconnected nanoparticles. This electron transfer results inan effective separation of charge and the desired photovoltaic effect.Accordingly, the electrons in the conduction band of the interconnectednanoparticles are made available to drive an external load.

The dye(s) can be sorbed (e.g., chemisorbed and/or physisorbed) on thenanoparticles. A dye can be selected, for example, based on its abilityto absorb photons in a wavelength range of operation (e.g., within thevisible spectrum), its ability to produce free electrons (or electronholes) in a conduction band of the nanoparticles, its effectiveness incomplexing with or sorbing to the nanoparticles, and/or its color.

In some embodiments, photoactive layer 350 can further include one ormore co-sensitizers that adsorb with a sensitizing dye to the surface ofan interconnected semiconductor oxide nanoparticle material, which canincrease the efficiency of a DSSC (e.g., by improving charge transferefficiency and/or reducing back transfer of electrons from theinterconnected semiconductor oxide nanoparticle material to thesensitizing dye). The sensitizing dye and the co-sensitizer may be addedtogether or separately when forming the photosensitized interconnectednanoparticle material. The co-sensitizer can donate electrons to anacceptor to form stable cation radicals, which can enhance theefficiency of charge transfer from the sensitizing dye to thesemiconductor oxide nanoparticle material and/or can reduce backelectron transfer to the sensitizing dye or co-sensitizer. Theco-sensitizer can include (1) conjugation of the free electron pair on anitrogen atom with the hybridized orbitals of the aromatic rings towhich the nitrogen atom is bonded and, subsequent to electron transfer,the resulting resonance stabilization of the cation radicals by thesehybridized orbitals; and/or (2) a coordinating group, such as a carboxyor a phosphate, the function of which is to anchor the co-sensitizer tothe semiconductor oxide. Examples of suitable co-sensitizers includearomatic amines (e.g., color such as triphenylamine and itsderivatives), carbazoles, and other fused-ring analogues. Examples ofphotoactive layers including co-sensitizers are disclosed, for example,in co-pending and commonly owned U.S. Ser. No. 10/350,919 [KON-010],which is hereby incorporated by reference.

In some embodiments, photoactive layer 350 can further includemacroparticles of the semiconductor material, where at least some of thesemiconductor macroparticles are chemically bonded to each other, and atleast some of the semiconductor nanoparticles are bonded tosemiconductor macroparticles. The dye(s) are sorbed (e.g., chemisorbedand/or physisorbed) on the semiconductor material. Macroparticles refersto a collection of particles having an average particle size of at leastabout 100 nanometers (e.g., at least about 150 nanometers, at leastabout 200 nanometers, at least about 250 nanometers). Examples ofphotovoltaic cells including macroparticles in the photoactive layer aredisclosed, for example, in co-pending and commonly owned U.S. Ser. No.60/589,423 [KON-023], which is hereby incorporated by reference.

In certain embodiments, a DSSC can include a coating that can enhancethe adhesion of a photovoltaic material to a base material (e.g., usingrelatively low process temperatures, such as less than about 300° C.).Such photovoltaic cells and methods are disclosed, for example, inco-pending and commonly owned U.S. Ser. No. 10/351,260 [KON-008], whichis hereby incorporated by reference.

The composition and thickness of electrically conductive layer 320 isgenerally selected based on desired electrical conductivity, opticalproperties, and/or mechanical properties of the layer. In someembodiments, layer 320 is transparent. Examples of transparent materialssuitable for forming such a layer include certain metal oxides, such asindium tin oxide (ITO), tin oxide, and a fluorine-doped tin oxide. Insome embodiments, electrically conductive layer 320 can be formed of afoil (e.g., a titanium foil). Electrically conductive layer 320 may be,for example, between about 100 nm and 500 nm thick, (e.g., between about150 nm and 300 nm thick).

In certain embodiments, electrically conductive layer 320 can be opaque(i.e., can transmit less than about 10% of the visible spectrum energyincident thereon). For example, layer 320 can be formed from acontinuous layer of an opaque metal, such as copper, aluminum, indium,or gold. In some embodiments, an electrically conductive layer can havean interconnected nanoparticle material formed thereon. Such layers canbe, for example, in the form of strips (e.g., having a controlled sizeand relative spacing, between first and second flexible substrates).Examples of such DSSCs are disclosed, for example, in co-pending andcommonly owned U.S. Ser. No. 10/351,251 [KON-013], which is herebyincorporated by reference.

In some embodiments, electrically conductive layer 320 can include adiscontinuous layer of a conductive material. For example, electricallyconductive layer 320 can include an electrically conducting mesh.Suitable mesh materials include metals, such as palladium, titanium,platinum, stainless steels and alloys thereof. In some embodiments, themesh material includes a metal wire. The electrically conductive meshmaterial can also include an electrically insulating material that hasbeen coated with an electrically conducting material, such as a metal.The electrically insulating material can include a fiber, such as atextile fiber or monofilament. Examples of fibers include syntheticpolymeric fibers (e.g., nylons) and natural fibers (e.g., flax, cotton,wool, and silk). The mesh electrically conductive layer can be flexibleto facilitate, for example, formation of the DSSC by a continuousmanufacturing process. Photovoltaic cells having mesh electricallyconductive layers are disclosed, for example, in co-pending and commonlyowned U.S. Ser. Nos. 10/395,823; 10/723,554 and 10/494,560 [KON-015,KON-018 and KON-025, respectively], each of which is hereby incorporatedby reference.

The mesh electrically conductive layer may take a wide variety of formswith respect to, for example, wire (or fiber) diameters and meshdensities (i.e., the number of wires (or fibers) per unit area of themesh). The mesh can be, for example, regular or irregular, with anynumber of opening shapes. Mesh form factors (such as, e.g., wirediameter and mesh density) can be chosen, for example, based on theconductivity of the wire (or fibers) of the mesh, the desired opticaltransmissivity, flexibility, and/or mechanical strength. Typically, themesh electrically conductive layer includes a wire (or fiber) mesh withan average wire (or fiber) diameter in the range from about one micronto about 400 microns, and an average open area between wires (or fibers)in the range from about 60% to about 95%.

Catalyst layer 330 is generally formed of a material that can catalyze aredox reaction in the charge carrier layer positioned below. Examples ofmaterials from which catalyst layer can be formed include platinum andpolymers, such as polythiophenes, polypyrroles, polyanilines and theirderivatives. Examples of polythiophene derivatives includepoly(3,4-ethylenedioxythiophene) (“PEDOT”), poly(3-butylthiophene),poly[3-(4-octylphenyl)thiophene], poly(thieno[3,4-b]thiophene)(“PT34bT”), andpoly(thieno[3,4-b]thiophene-co-3,4-ethylenedioxythiophene)(“PT34bT-PEDOT”). Examples of catalyst layers containing one or morepolymers are disclosed, for example, in co-pending and commonly ownedU.S. Ser. Nos. 10/897,268 and 60/637,844 [KON-016 and KON-028], both ofwhich are hereby incorporated by reference.

Substrate 310 can be formed from a mechanically-flexible material, suchas a flexible polymer, or a rigid material, such as a glass. Examples ofpolymers that can be used to form a flexible substrate includepolyethylene naphthalates (PEN), polyethylene terephthalates (PET),polyethyelenes, polypropylenes, polyamides, polymethylmethacrylate,polycarbonate, and/or polyurethanes. Flexible substrates can facilitatecontinuous manufacturing processes such as web-based coating andlamination. However, rigid substrate materials may also be used, such asdisclosed, for example, in co-pending and commonly owned U.S. Ser. No.10/351,265 [KON-012], which is hereby incorporated by reference.

The thickness of substrate 310 can vary as desired. Typically, substratethickness and type are selected to provide mechanical support sufficientfor the DSSC to withstand the rigors of manufacturing, deployment, anduse. Substrate 310 can have a thickness of from about six microns toabout 5,000 microns (e.g., from about 6 microns to about 50 microns,from about 50 microns to about 5,000 microns, from about 100 microns toabout 1,000 microns). In embodiments where electrically conductive layer320 is transparent, substrate 310 is formed from a transparent material.For example, substrate 310 can be formed from a transparent glass orpolymer, such as a silica-based glass or a polymer, such as those listedabove. In such embodiments, electrically conductive layer 320 may alsobe transparent.

Substrate 370 and electrically conductive layer 360 can be as describedabove regarding substrate 310 and electrically conductive layer 320,respectively. For example, substrate 370 can be formed from the samematerials and can have the same thickness as substrate 310. In someembodiments however, it may be desirable for substrate 370 to bedifferent from 310 in one or more aspects. For example, where the DSSCis manufactured using a process that places different stresses on thedifferent substrates, it may be desirable for substrate 370 to be moreor less mechanically robust than substrate 310. Accordingly, substrate370 may be formed from a different material, or may have a differentthickness that substrate 310. Furthermore, in embodiments where only onesubstrate is exposed to an illumination source during use, it is notnecessary for both substrates and/or electrically conducting layers tobe transparent. Accordingly, one of substrates and/or correspondingelectrically conducting layer can be opaque.

Generally, charge carrier layer 340 includes a material that facilitatesthe transfer of electrical charge from a ground potential or a currentsource to photoactive layer 350. A general class of suitable chargecarrier materials include solvent-based liquid electrolytes,polyelectrolytes, polymeric electrolytes, solid electrolytes, n-type andp-type transporting materials (e.g., conducting polymers) and gelelectrolytes. Examples of gel electrolytes are disclosed, for example,in co-pending and commonly owned U.S. Ser. No. 10/350,912 [KON-004],which is hereby incorporated by reference. Other choices for chargecarrier media are possible. For example, the charge carrier layer caninclude a lithium salt that has the formula LiX, where X is an iodide,bromide, chloride, perchlorate, thiocyanate, trifluoromethyl sulfonate,or hexafluorophosphate.

The charge carrier media typically includes a redox system. Suitableredox systems may include organic and/or inorganic redox systems.Examples of such systems include cerium(III) sulphate/cerium(IV), sodiumbromide/bromine, lithium iodide/iodine, Fe²⁺/Fe³⁺, Co²⁺/Co³⁺, andviologens. Furthermore, an electrolyte solution may have the formulaM_(i)X_(j), where i and j are greater than or equal to one, where X isan anion, and M is lithium, copper, barium, zinc, nickel, a lanthanide,cobalt, calcium, aluminum, or magnesium. Suitable anions includechloride, perchlorate, thiocyanate, trifluoromethyl sulfonate, andhexafluorophosphate.

In some embodiments, the charge carrier media includes a polymericelectrolyte. For example, the polymeric electrolyte can includepoly(vinyl imidazolium halide) and lithium iodide and/or polyvinylpyridinium salts. In embodiments, the charge carrier media can include asolid electrolyte, such as lithium iodide, pyridimum iodide, and/orsubstituted imidazolium iodide.

The charge carrier media can include various types of polymericpolyelectrolytes. For example, suitable polyelectrolytes can includebetween about 5% and about 95% (e.g., 5-60%, 5-40%, or 5-20%) by weightof a polymer, e.g., an ion-conducting polymer, and about 5% to about 95%(e.g., about 35-95%, 60-95%, or 80-95%) by weight of a plasticizer,about 0.05 M to about 10 M of a redox electrolyte of organic orinorganic iodides (e.g., about 0.05-2 M, 0.05-1 M, or 0.05-0.5 M), andabout 0.01 M to about 1 M (e.g., about 0.05-0.5 M, 0.05-0.2 M, or0.05-0.1 M) of iodine. The ion-conducting polymer may include, forexample, polyethylene oxide (PEO), polyacrylonitrile (PAN),polymethylmethacrylate (PMMA), polyethers, and polyphenols. Examples ofsuitable plasticizers include ethyl carbonate, propylene carbonate,mixtures of carbonates, organic phosphates, butyrolactone, anddialkylphthalates.

In some embodiments, charge carrier layer 340 can include one or morezwitterionic compounds. In general, the zwitterionic compound(s) havethe formula:

R₁ is a cationic heterocyclic moiety, a cationic ammonium moiety, acationic guanidinium moiety, or a cationic phosphonium moiety. R₁ can beunsubstituted or substituted (e.g., alkyl substituted, alkoxysubstituted, poly(ethyleneoxy) substituted, nitrogen-substituted).Examples of cationic substituted heterocyclic moieties include cationicnitrogen-substituted heterocyclic moieties (e.g., alkyl imidazolium,piperidinium, pyridinium, morpholinium, pyrimidinium, pyridazinium,pyrazinium, pyrazolium, pyrrolinium, thiazolium, oxazolium, triazolium).Examples of cationic substituted ammonium moieties include cationicalkyl substituted ammonium moieties (e.g., symmetrictetraalkylammonium). Examples of cationic substituted guanidiniummoieties include cationic alkyl substituted guanidinium moieties (e.g.,pentalkyl guanidinium. R₂ is an anoinic moiety that can be:

where R₃ is H or a carbon-containing moiety selected from C_(x) alkyl,C_(x+1) alkenyl, C_(x+1) alkynyl, cycloalkyl, heterocyclyl and aryl; andx is at least 1 (e.g., two, three, four, five, six, seven, eight, nine,10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20). In some embodiments, acarbon-containing moiety can be substituted (e.g., halo substituted). Ais (C(R₃)₂)_(n), where: n is zero or greater (e.g., one, two, three,four, five, six, seven, eight, nine, 10, 11, 12, 13, 14, 15, 16, 17, 18,19, 20); and each R₃ is independently as described above. Charge carrierlayers including one or more zwitterionic compounds are disclosed, forexample, in co-pending and commonly owned U.S. Ser. No. 11/000,276[KON-017], which is hereby incorporated by reference.

FIG. 4 shows a process (a roll-to-roll process) 400 for manufacturing aDSSC by advancing a substrate 402 between rollers 412. Substrate 402 canbe advanced between rollers 430 continuously, periodically, orirregularly during a manufacturing run.

An electrically conductive layer 420 (e.g., a titanium foil) is attachedto substrate 402 adjacent location 428.

An interconnected nanoparticle material is then formed on theelectrically conductive layer adjacent location 410. The interconnectednanoparticle material can be formed by applying a solution containing alinking agent (e.g., polymeric linking agent, such as poly(n-butyltitanate)) and metal oxide nanoparticles (e.g., titania). In someembodiments, the polymeric linking agent and the metal oxidenanoparticles are separately applied to form the interconnectednanoparticle material. The polymeric linking agent and metal oxidenanoparticles can be heated (e.g., in an oven present in the system usedin the roll-to-roll process) to form the interconnected nanoparticlematerial.

One or more dyes are then applied (e.g., using silk screening, ink jetprinting, or gravure printing) to the interconnected nanoparticlematerial adjacent location 434 to form a photoactive layer.

A charge carrier layer is deposited onto the patterned photoactive layeradjacent location 414. The charge carrier layer can be deposited usingknown techniques, such as those noted above.

An electrically conductive layer 422 (e.g., ITO) is attached tosubstrate 424 adjacent location 432.

A catalyst layer precursor is deposited on electrically conductive layer422 adjacent location 418. The catalyst layer precursor can be depositedon electrically conductive layer 422 using, for example, electrochemicaldeposition using chloroplatinic acid in an electrochemical cell, orpyrolysis of a coating containing a platinum compound (e.g.,chloroplatinic acid). In general, the catalyst layer precursor can bedeposited using known coating techniques, such as spin coating, dipcoating, knife coating, bar coating, spray coating, roller coating, slotcoating, gravure coating, screen coating, and/or ink jet printing. Thecatalyst layer precursor is then heated (e.g., in an oven present in thesystem used in the roll-to-roll process) to form the catalyst layer. Insome embodiments, electrically conductive material 360 can be at leastpartially coated with the catalyst layer before attaching to advancingsubstrate 424. In certain embodiments, the catalyst layer is applieddirectly to electrically conductive layer 422 (e.g., without thepresence of a precursor).

In some embodiments, the method can include scoring the coating of afirst coated base material at a temperature sufficiently elevated topart the coating and melt at least a portion of the first base material,and/or scoring a coating of a second coated base material at atemperature sufficiently elevated to part the coating and at least aportion of the second base material, and optionally joining the firstand second base materials to form a photovoltaic module. DSSCs withmetal foil and methods for the manufacture are disclosed, for example,in co-pending and commonly owned U.S. Ser. No. 10/351,264 [KON-011],which is hereby incorporated by reference.

In certain embodiments, the method can include slitting (e.g.,ultrasonic slitting) to cut and/or seal edges of photovoltaic cellsand/or modules (e.g., to encapsulate the photoactive components in anenvironment substantially impervious to the atmosphere). Examples ofsuch methods are disclosed, for example, in co-pending and commonlyowned U.S. Ser. No. 10/351,250 [KON-014], which is hereby incorporatedby reference.

In general, multiple photovoltaic cells can be electrically connected toform a photovoltaic system. As an example, FIG. 5 is a schematic of aphotovoltaic system 500 having a module 510 containing photovoltaiccells 520. Cells 520 are electrically connected in series, and system500 is electrically connected to a load 530. As another example, FIG. 6is a schematic of a photovoltaic system 500 having a module 510 thatcontains photovoltaic cells 520. Cells 520 are electrically connected inparallel, and system 500 is electrically connected to a load 530. Insome embodiments, some (e.g., all) of the photovoltaic cells in aphotovoltaic system can have one or more common substrates. In certainembodiments, some photovoltaic cells in a photovoltaic system areelectrically connected in series, and some of the photovoltaic cells inthe photovoltaic system are electrically connected in parallel. Incertain embodiments, adjacent cell can be in electrical contact via awire. Photovoltaic modules having such architectures are disclosed, forexample, in co-pending and commonly owned U.S. Ser. No. 10/351,298[KON-007], which is hereby incorporated by reference. In someembodiments, adjacent cells can be in electrical contact via aconductive interconnect (e.g., a stitch) that is disposed in anelectrically conductive layer in each of the adjacent cells.Photovoltaic modules having such architecture are disclosed, forexample, in co-pending and commonly owned U.S. Ser. No. 60/575,971[KON-020], which is hereby incorporated by reference. In certainembodiments, adjacent cells can be electrically connected by disposing ashaped (e.g., dimpled, embossed) portion in an electrically conductivelayer of one of the cells, where the shaped portion extends through anadhesive and makes electrical contact with an electrically conductivelayer in an adjacent cell. With this arrangement, the cells can be inelectrical contact without using a separate interconnect component.Photovoltaic modules having such architecture are disclosed, forexample, in co-pending and commonly owned U.S. Ser. No. 60/590,312[KON-026], which is hereby incorporated by reference. In someembodiments, adjacent cells can be electrically connected via anadhesive material and a mesh partially disposed in the adhesivematerial. Photovoltaic modules having such architecture are disclosed,for example, in co-pending and commonly owned U.S. Ser. No. 60/590,313[KON-027], which is hereby incorporated by reference. In certainembodiments, a first group of photovoltaic modules are formed on a firstregion of a substrate, while a second group of photovoltaic modules areformed on a second region of the same substrate. The substrate may thenbe physically divided, or in some embodiments folded, to combine therespective photovoltaic module portions to produce a final photovoltaicmodule. The interconnections between the photovoltaic cells of the finalmodule can be parallel, serial, or a combination thereof. Photovoltaiccells having such architecture are disclosed, for example, in U.S. Pat.No. 6,706,963 [KON-001], which is hereby incorporated by reference.

FIG. 7 shows a polymer photovoltaic cell 600 that includes substrates610 and 670, electrically conductive layers 620 and 660, a hole blockinglayer 630, a photoactive layer 640, and a hole carrier layer 650.

In general, substrate 610 and/or substrate 670 can be as described abovewith respect to the substrates in a DSSC. Exemplary materials includepolyethylene tereplithalate (PET), polyethylene naphthalate (PEN), or apolyimide. An example of a polyimide is a KAPTON® polyimide film(available from E. I. du Pont de Nemours and Co.).

Generally, electrically conductive layer 620 and/or electricallyconductive layer 670 can be as described with respect to theelectrically conductive layers in a DSSC.

Hole blocking layer 630 is generally formed of a material that, at thethickness used in photovoltaic cell 600, transports electrons toelectrically conductive layer 620 and substantially blocks the transportof holes to electrically conductive layer 620. Examples of materialsfrom which layer 630 can be formed include LiF, metal oxides (e.g., zincoxide, titanium oxide) and combinations thereof. While the thickness oflayer 630 can generally be varied as desired, this thickness istypically at least 0.02 micron (e.g., at least about 0.03 micron, atleast about 0.04 micron, at least about 0.05 micron) thick and/or atmost about 0.5 micron (e.g., at most about 0.4 micron, at most about 0.3micron, at most about 0.2 micron, at most about 0.1 micron) thick. Insome embodiments, this distance is from 0.01 micron to about 0.5 micron.In some embodiments, layer 630 is a thin LiF layer. Such layers aredisclosed, for example, in co-pending and commonly owned U.S. Ser. No.10/258,708 [Q-04], which is hereby incorporated by reference.

Hole carrier layer 650 is generally formed of a material that, at thethickness used in photovoltaic cell 600, transports holes toelectrically conductive layer 660 and substantially blocks the transportof electrons to electrically conductive layer 660. Examples of materialsfrom which layer 650 can be formed include polythiophenes (e.g., PEDOT),polyanilines, polyvinylcarbazoles, polyphenylenes, polyphenylvinylenes,polysilanes, polythienylenevinylenes, polyisothianaphthanenes andcombinations thereof. While the thickness of layer 650 can generally bevaried as desired, this thickness is typically at least 0.01 micron(e.g., at least about 0.05 micron, at least about 0.1 micron, at leastabout 0.2 micron, at least about 0.3 micron, at least about 0.5 micron)and/or at most about five microns (e.g., at most about three microns, atmost about two microns, at most about one micron). In some embodiments,this distance is from 0.01 micron to about 0.5 micron.

Photoactive layer 640 generally includes an electron acceptor materialand an electron donor material.

Examples of electron acceptor materials include formed of fullerenes,oxadiazoles, carbon nanorods, discotic liquid crystals, inorganicnanoparticles (e.g., nanoparticles formed of zinc oxide, tungsten oxide,indium phosphide, cadmium selenide and/or lead sulphide), inorganicnanorods (e.g., nanorods formed of zinc oxide, tungsten oxide, indiumphosphide, cadmium selenide and/or lead sulphide), or polymerscontaining moieties capable of accepting electrons or forming stableanions (e.g., polymers containing CN groups, polymers containing CF₃groups). In some embodiments, the electron acceptor material is asubstituted fullerene (e.g., PCBM). In some embodiments, the fullerenescan be derivatized. For example, a fullerene derivative can includes afullerene (e.g., PCBG), a pendant group (e.g., a cyclic ether such asepoxy, oxetane, or furan) and a linking group that spaces the pendantgroup apart from the fullerene. The pendant group is generallysufficiently reactive that fullerene derivative may be reacted withanother compound (e.g., another fullerene derivative) to prepare areaction product. Photoactive layers including derivatized fullerenesare disclosed, for example, in co-pending and commonly owned U.S. Ser.No. 60/576,033 [KON-021], which is hereby incorporated by reference.Combinations of electron acceptor materials can be used.

Examples of electron donor materials include discotic liquid crystals,polythiophenes, polyphenylenes, polyphenylvinylenes, polysilanes,polythienylvinylenes, and polyisothianaphthalenes. In some embodiments,the electron donor material is poly(3-hexylthiophene). In certainembodiments, photoactive layer 640 can include a combination of electrondonor materials.

In some embodiments, photoactive layer 640 includes an oriented electrondonor material (e.g., a liquid crystal (LC) material), an electroactivepolymeric binder carrier (e.g., a poly(3-hexylthiophene) (P3HT)material), and a plurality of nanocrystals (e.g., oriented nanorodsincluding at least one of ZnO, WO₃, or TiO₂). The liquid crystal (LC)material can be, for example, a discotic nematic LC material, includinga plurality of discotic mesogen units. Each unit can include a centralgroup and a plurality of electroactive arms. The central group caninclude at least one aromatic ring (e.g., an anthracene group). Eachelectroactive arm can include a plurality of thiophene moieties and aplurality of alkyl moities. Within the photoactive layer, the units canalign in layers and columns. Electroactive arms of units in adjacentcolumns can interdigitate with one another facilitating electrontransfer between units. Also, the electroactive polymeric carrier can bedistributed amongst the LC material to further facilitate electrontransfer. The surface of each nanocrystal can include a plurality ofelectroactive surfactant groups to facilitate electron transfer from theLC material and polymeric carrier to the nanocrystals. Each surfactantgroup can include a plurality of thiophene groups. Each surfactant canbe bound to the nanocrystal via, for example, a phosphonic end-group.Each surfactant group also can include a plurality of alkyl moieties toenhance solubility of the nanocrystals in the photoactive layer.Examples of photovoltaic cells are disclosed, for example, in co-pendingand commonly owned U.S. Ser. No. 60/664,298, filed Mar. 22, 2005[KON-024], which is hereby incorporated by reference.

In certain embodiments, the electron donor and electron acceptormaterials in layer 640 can be selected so that the electron donormaterial, the electron acceptor material and their mixed phases have anaverage largest grain size of less than 500 nanometers in at least somesections of layer 640. In such embodiments, preparation of layer 640 caninclude using a dispersion agent (e.g., chlorobenzene) as a solvent forboth the electron donor and the electron acceptor. Such photoactivelayers are disclosed, for example, in co-pending and commonly owned U.S.Ser. No. 10/258,713 [Q-03], which is hereby incorporated by reference.

Generally, photoactive layer 640 is sufficiently thick to be relativelyefficient at absorbing photons impinging thereon to form correspondingelectrons and holes, and sufficiently thin to be relatively efficient attransporting the holes and electrons to the electrically conductivelayers of the device. In certain embodiments, layer 640 is at least 0.05micron (e.g., at least about 0.1 micron, at least about 0.2 micron, atleast about 0.3 micron) thick and/or at most about one micron (e.g., atmost about 0.5 micron, at most about 0.4 micron) thick. In someembodiments, layer 640 is from 0.1 micron to about 0.2 micron thick.

In some embodiments, the transparency of photoactive layer 640 canchange as an electric field to which layer 640 is exposed changes. Suchphotovoltaic cells are disclosed, for example, in co-pending andcommonly owned U.S. Ser. No. 10/486,116 [Q-01], which is herebyincorporated by reference.

In some embodiments, cell 600 can further include an additional layer(e.g., formed of a conjugated polymer, such as a dopedpoly(3-alkylthiophene)) between photoactive layer 640 and electricallyconductive layer 620, and/or an additional layer (e.g., formed of aconjugated polymer) between photoactive layer 640 and electricallyconductive layer 660. The additional layer(s) can have a band gap (e.g.,achieved by appropriate doping) of 1.8 eV. Such photovoltaic cells aredisclosed, for example, in U.S. Pat. No. 6,812,399 [Q-05], which ishereby incorporated by reference.

Optionally, cell 600 can further include a thin LiF layer betweenphotoactive layer 640 and electrically conductive layer 660. Such layersare disclosed, for example, in co-pending and commonly owned U.S. Ser.No. 10/258,708 [Q-04], which is hereby incorporated by reference.

In some embodiments, cell 600 can be prepared as follows. Electricallyconductive layer 620 is formed upon substrate 610 using conventionaltechniques. Electrically conductive layer 620 is configured to allow anelectrical connection to be made with an external load. Layer 630 isformed upon electrically conductive layer 620 using, for example, asolution coating process, such as slot coating, spin coating or gravurecoating. Photoactive layer 640 is formed upon layer 630 using, forexample, a solution coating process. Layer 650 is formed on photoactivelayer 640 using, for example, a solution coating process, such as slotcoating, spin coating or gravure coating. Electrically conductive layer620 is formed upon layer 650 using, for example, a vacuum coatingprocess, such as evaporation or sputtering.

In certain embodiments, preparation of cell 600 can include a heattreatment above the glass transition temperature of the electron donormaterial for a predetermined treatment time. To increase efficiency, theheat treatment of the photovoltaic cell can be carried out for at leasta portion of the treatment time under the influence of an electric fieldinduced by a field voltage applied to the electrically conductive layersof the photovoltaic cell and exceeding the no-load voltage thereof. Suchmethods are disclosed, for example, in co-pending and commonly ownedU.S. Ser. No. 10/509,935 [Q-02], which is hereby incorporated byreference.

In general, a module containing multiple polymer photovoltaic cells canbe arranged as described above with respect to DSSC modules containingmultiple DSSCs.

Generally, polymer photovoltaic cells can be arranged with thearchitectures described above with respect to the architectures ofDSSCs.

While certain embodiments of photovoltaic cells have been described,other embodiments are also known.

As an example, a photovoltaic cell can be in the shape of a fiber (e.g.,a flexible fabric or textile). Examples of such photovoltaic cells aredescribed, for example, in co-pending and commonly owned U.S. Ser. No.10/351,607 [KON-002], which is hereby incorporated by reference. FIG. 8depicts an illustrative embodiment of photovoltaic fiber 800 thatincludes an electrically conductive fiber core 802, a significantlylight transmitting electrical conductor 806, and a photoconversionmaterial 810, which is disposed between the electrically conductivefiber core 802 and the significantly light transmitting electricalconductor 806.

The electrically conductive fiber core 802 may take many forms. In theembodiment illustrated in FIG. 8, the electrically conductive fiber core802 is substantially solid. In other embodiments, electricallyconductive fiber core 802 may be substantially hollow. Thephotoconversion material 810 may include a photosensitized nanomatrixmaterial and a charge carrier material. The charge carrier material mayform a layer, be interspersed with the photosensitized nanomatrixmaterial, or be a combination of both. The photosensitized nanomatrixmaterial is adjacent to the electrically conductive fiber core. Thecharge carrier material is adjacent to the electrically conductive fibercore.

FIG. 9 depicts a photovoltaic material 900 that includes a fiber 902,one or more wires 904 that are imbedded in a significantly lighttransmitting electrical conductor 906, a photosensitized nanomatrixmaterial 912, a charge carrier material 915, and a protective layer 924.The wires 904 may also be partially imbedded in the charge carriermaterial 915 to, for example, facilitate electrical connection of thephotovoltaic material 900 to an external load, to reinforce thesignificantly light transmitting electrical conductor 906, and/or tosustain the flexibility of the photovoltaic material 900. Preferably,the wire 904 is an electrical conductor and, in particular, a metalelectrical conductor. Suitable wire 904 materials include, but are notlimited to, copper, silver, gold, platinum, nickel, palladium, iron, andalloys thereof. In one illustrative embodiment, the wire 904 is betweenabout 0.5 μm and about 100 μm thick. In another illustrative embodiment,the wire 904 is between about 1 μm and about 10 μm thick.

FIG. 10 shows a method of forming a photovoltaic material 1000 that hasan electrically conductive fiber core, a significantly lighttransmitting electrical conductor, and a photoconversion material, whichis disposed between the electrically conductive fiber core and thesignificantly light transmitting electrical conductor. According to themethod, the outer surface of the conductive fiber core is coated withtitanium dioxide nanoparticles. The nanoparticles are theninterconnected by, for example, sintering, or preferably by contactingthe nanoparticles with a reactive polymeric linking agent such as, forexample, poly(n-butyl titanate), which is described in more detailbelow. The interconnected titanium dioxide nanoparticles are thencontacted with a photosensitizing agent, such as, for example, a 3×10−4M N3-dye solution for 1 hour, to form a photosensitized nanomatrixmaterial. A charge carrier material that includes a gelled electrolyteis then coated on the photosensitized nanomatrix material to completethe photoconversion material. A strip 625 of transparent polymer fromabout 2.5 μm to about 6 μm thick, coated with a layer of ITO that inturn has been platinized, is wrapped in a helical pattern about thephotovoltaic material 1000 with the platinized side of the strip 1025 incontact with the charge carrier material. In this illustrativeembodiment, the strip 1025 of transparent polymer is the significantlylight transmitting electrical conductor. In other illustrativeembodiments, the significantly light transmitting electrical conductoris formed using the materials described in connection with thisapplication and the applications that are incorporated by reference.

Referring to FIG. 11, in another illustrative embodiment, a photovoltaicmaterial 1100 is formed by wrapping a platinum or platinized wire 1105around a core 1127 including a photoconversion material disposed oneither an electrically conductive fiber core or on an inner electricalconductor in turn disposed on an insulative fiber. A strip 1150 oftransparent polymer coated with a layer of ITO, which has beenplatinized, is wrapped in a helical pattern about the core 1127 with theplatinized side of the strip 1150 in contact with the wire 1105 and thecharge carrier material of the core 1127.

FIGS. 12A, 12B, and 12C depict other illustrative embodiments of aphotovoltaic material 1200, constructed in accordance with theinvention. The photovoltaic material 1200 includes a metal-textile fiber1201, which has metallic electrically conductive portions 1202 andtextile portions 1203. The textile portions 1203 may be electricallyconductive or may be insulative and coated with an electrical conductor.Referring to FIG. 12B, a dispersion of titanium dioxide nanoparticles iscoated on the outer surface of portions of the textile portions 1203 ofthe metal-textile fiber 1201. The particles are then interconnectedpreferably by contacting the nanoparticles with a reactive polymericlinking agent such as poly(n-butyl titanate), which is further describedbelow. The interconnected titanium dioxide nanoparticles are thencontacted with a photosensitizing agent, such as a N3 dye solution, for1 hour to form a photosensitized nanomatrix material 1212.

Referring to FIG. 12C, a charge carrier material 1215 including a solidelectrolyte is then coated on the textile portions 1203. A strip 1225 ofPET coated with ITO, that in turn has been platinized, is disposed onthe photosensitized nanomatrix material 1212 and the charge carriermaterial 1215. The platinized ITO is in contact with the charge carriermaterial 1215.

As indicated, the photovoltaic fibers may be utilized to form aphotovoltaic fabric. The resultant photovoltaic fabric may be aflexible, semi-rigid, or rigid fabric. The rigidity of the photovoltaicfabric may be selected, for example, by varying the tightness of theweave, the thickness of the strands of the photovoltaic materials used,and/or the rigidity of the photovoltaic materials used. The photovoltaicmaterials may be, for example, woven with or without other materials toform the photovoltaic fabric. In addition, strands of the photovoltaicmaterial, constructed according to the invention, may be welded togetherto form a fabric.

FIG. 13 depicts one illustrative embodiment of a photovoltaic fabric1300 that includes photovoltaic fibers 1301, according to the invention.As illustrated, the photovoltaic fabric 1300 also includesnon-photovoltaic fibers 1303. In various illustrative embodiments, thenon-photovoltaic fibers 1303 may be replaced with photovoltaic fibers.FIG. 13 also illustrates anodes 1310 and cathodes 1320 that are formedon the photovoltaic fabric 1300 and that may be connected to an externalload to form an electrical circuit. The anodes 1310 may be formed by aconductive fiber core or an electrical conductor on an insulative fiber,and the cathodes 1320 may be formed by significantly light transmittingelectrical conductors. In FIG. 13, each edge of the photovoltaic fabric1300 is constructed in an alternating fashion with the anodes 1310 andcathodes 1320 formed from photovoltaic fibers 1301. In anotherillustrative embodiment, each edge of photovoltaic fabric 1300 isconstructed from just one anode or just one cathode, both of which areformed from either photovoltaic fibers, non-photovoltaic fibers, or acombination of both.

FIG. 14 shows a photovoltaic fabric 1400 formed by a two-componentphotovoltaic material. According to the illustrative embodiment, eachcomponent is formed by a mesh, where one mesh serves as the anode 1410and the other as the cathode 1420. Each mesh (or component) is connectedto a different busbar, which in turn may be connected to oppositeterminals of an external load. Hence, a single large-area, fabric-likephotovoltaic cell is produced.

According to the illustrated embodiment, the mesh material may be anymaterial suitable as a fiber material. For example, the mesh materialmay include electrically conductive fiber cores, electrically insulativefiber cores coated with an electrical conductor, or a combination ofboth. In one embodiment, the anode mesh is made of a metal fiber with aredox potential approximately equal to that of ITO. In anotherembodiment, the mesh is composed of a plastic fiber, e.g., nylon that ismetalized by, for example, vacuum deposition or electroless deposition.

In one illustrative embodiment, the anode 1410 mesh of the photovoltaicfabric 1400 is formed by coating the mesh with a dispersion of titaniumdioxide nanoparticles by, for example, dipping or slot coating in asuspension. The titanium dioxide nanoparticles are interconnected, forexample, by a sintering, or preferably by a reactive polymeric linkingagent, such as poly(n-butyl titanate) described in more detail below.After coating with the titania suspension, but prior to either sinteringor crosslinking, an air curtain can be used to remove excess titaniafrom the spaces between the fibers of the mesh. Likewise, this, or someother functionally equivalent method, may be used to clear these spacesof excess material after each of the subsequent steps in the preparationof the final photovoltaic fabric. Subsequently, the mesh is slot coatedor dipped in a photosensitizing agent solution, such as N3 dye, followedby washing and drying. A charge carrier including a solid electrolyte(e.g., a thermally-reversible polyelectrolyte) is applied to the mesh tofrom the anode 1410 mesh. In another illustrative embodiment, thecathode 1420 mesh of the photovoltaic fabric 1400 is formed as aplatinum-coated mesh, such as, for example, a platinum-coated conductivefiber core mesh or a platinum-coated plastic mesh.

To form the photovoltaic fabric 1400, the anode 1410 mesh and cathode1420 mesh are brought into electrical contact and aligned one over theother, so that the strands of each mesh are substantially parallel toone another. Perfect alignment is not critical. In fact, it may beadvantageous from the standpoint of photon harvesting to slightlymisalign the two meshes. The photovoltaic fabric 1400 may be coated witha solution of a polymer that serves as a protective, transparent,flexible layer.

One of the advantages of the photovoltaic fabric 1400 is its relativeease of construction and the ease with which the anode 1410 and cathode1420 may be connected to an external circuit. For example, the edges ofeach mesh, one edge, multiple edges, or all edges may be left uncoatedwhen the coating operations described above are performed. The anode1410 and cathode 1420 are each electrically connected to its own metalbusbar. An advantage of this illustrative embodiment is the eliminationof the possibility that severing one wire would disable the entirephotovoltaic fabric.

As another example, a photovoltaic cell may further include one or morespacing elements disposed between the electrically conductive layers.Examples of spacing elements include spheres, mesh(es) and porousmembrane(s). In certain embodiments, the spacing element(s) can maintaina distance (e.g., a substantially constant and/or substantially uniformdistance) between electrically conductive layers of different charge(e.g., during operation and/or bending of a photovoltaic cell). Thiscan, for example, reduce the likelihood that the electrically conductivelayer and photoactive material will contact each other. Photovoltaiccells having one or more spacing elements are disclosed, for example, inco-pending and commonly owned U.S. Ser. No. 11/033,217, filed Jan. 10,2005 [KON-019], which is hereby incorporated by reference.

As an additional example, in certain embodiments, a photovoltaic cellcan have an absorption maximum that is at relatively long wavelengthregion and/or relatively high layer efficiency. Such cells aredisclosed, for example, in published international applicationWO04/025746 [SA-5], which is hereby incorporated by reference.

As a further example, in some embodiments, the photoactive layer caninclude at least one mixture of two different fractions of a functionalpolymer (e.g., contained in a solvent). Such photovoltaic cells aredisclosed, for example, in co-pending and commonly owned U.S. Ser. No.10/515,159 [SA-7], which is hereby incorporated by reference.

As an additional example, in certain embodiments, a photovoltaic cellcan be a tandem cell in which two or more photoactive layers arearranged in tandem. Such cells can include of an optical and electricalseries connection of two photoactive layers. The cells can have at leastone shared electrically conductive layer (e.g., placed between twophotovoltaically active layers). Such photovoltaic cells are disclosed,for example, in published international application WO 2003/107453[SA-8], which is hereby incorporated by reference.

As another example, in some embodiments, a photovoltaic cell canoptionally include an additional layer having an asymmetric conductivityis placed between at least one of the electrically conductive layers andthe photoactive layer. Such photovoltaic cells are disclosed, forexample, in published international application WO 2004/112162 [SA-9],which is hereby incorporated by reference.

As an additional example, in some embodiments, the electricallyconductive layers can be formed of spherical allotropes (e.g., siliconand/or carbon nanotubes). The electrically conductive layers can eitherexclusively contain allotropes and/or contain allotropes that areembedded in an organic functional polymer. Such photovoltaic cells aredisclosed, for example, in published international applicationWO03/107451 [SA-15], which is hereby incorporated by reference.

As another example, in certain embodiments, one or more layers of aphotovoltaic cell can be structured. Such photovoltaic cells aredisclosed, for example, in published international applicationWO04/025747 [SA-16], which is hereby incorporated by reference.

As a further example, in some embodiments, a photovoltaic cell caninclude an improved top electrically conductive layer and to aproduction method therefor. The top electrically conductive layer ismade of an organic material that is applied, for example, by usingprinting techniques. Such photovoltaic cells are disclosed, for example,in published international application WO2004/051,756 [SA-17], which ishereby incorporated by reference.

Moreover, the photovoltaic devices and modules including thephotovoltaic devices can generally be used as a component in anyintended system. Examples of such systems include roofing, packagelabeling, battery chargers, sensors, window shades and blinds, awnings,opaque or semitransparent windows, and exterior wall panels. As anexample, one or more photovoltaic cells are incorporated into eyeglasses(e.g., sunglasses). Such sunglasses are disclosed, for example, inco-pending and commonly owned U.S. Ser. No. 10/504,091 [SA-2], which ishereby incorporated by reference. As another example, one or morephotovoltaic cells are incorporated into a thin film energy system. Thethin film energy system can include one or more thin film energyconverters that each include one or more photovoltaic cells. Suchsystems are disclosed, for example, in co-pending and commonly ownedU.S. Ser. No. 10/498,484 [SA-3], which is hereby incorporated byreference. As an additional example, a photovoltaic cell can be used ina flexible display (e.g., the photovoltaic cell can serve as a powersource for the flexible display). Examples of such flexible displays aredisclosed, for example, in co-pending and commonly owned U.S. Ser. No.10/350,812 [KON-005], which is hereby incorporated by reference. As afurther example, one or more photovoltaic cells are integrated into achip card. Such chip cards are disclosed, for example, in co-pending andcommonly owned WO 2004/017256, PCT/DE2003/002463 [SA-4], which is herebyincorporated by reference. As another example, a photovoltaic cell canbe used to power a multimedia greeting card or smart card. Suchphotovoltaic cells and systems are disclosed, for example, in U.S. Ser.No. 10/350,800 [KON-006], which is hereby incorporated by reference.

While DSSCs and polymer cells have been described, more generally anytype of photovoltaic cells can include one or more of the featuresdescribed above. As an example, in some embodiments, one or more hybridphotovoltaic cells can be used. In general, a hybrid photovoltaic cellhas a photoactive layer that includes one or more semiconductors, suchas a nanoparticle semiconductor; materials (e.g., one or more of thesemiconductor materials described above); and one or more polymermaterials that can act as an electron donor (e.g., one or more of thepolymer materials described above).

An aspect of the present invention relates to combining photovoltaicfacilities with sensors and other sensing facilities. While many of thephotovoltaic/sensor embodiments described herein describe particularphotovoltaic facilities and or particular sensor facilities, theseembodiments are merely examples; the applicants of the present inventionenvision many equivalent systems and methods which are encompassed bythe present invention. For example, a photovoltaic sensor facilityembodiment herein below may include a photovoltaic facility describedherein above; however, such photovoltaic facility may also comprise aphotovoltaic facility that is not described herein.

FIG. 15 illustrates a photovoltaic sensor facility 1500 according to theprinciples of the present invention. In embodiments, the photovoltaicsensor facility 1500 includes a photovoltaic facility 1502 and a sensingfacility 1504. In embodiments, the photovoltaic facility 1502 may be aphotovoltaic facility described herein above, such as those described inconnection with FIGS. 1-7, and it may be another type of photovoltaicfacility adapted to generate electricity from light. In embodiments, thesensing facility 1504 may be a facility adapted to sense, measure,assess, quantify, qualify, evaluate, monitor, gauge, calculate,determine, or otherwise sense. Examples of certain sensing facilities1504 are included in the embodiments below for further illustrativepurposes; however, these examples should not be construed as limiting;the applicants of the present invention envision many equivalents, andsuch equivalents are encompassed by the present invention. Inembodiments, the photovoltaic facility 1502 is adapted to power and isassociated with the sensor facility 1504. For example, a sensor mayrequire power to perform a certain function, and the photovoltaicfacility may be adapted to generate the requisite power and may beconnected to the sensor. In embodiments, the association between thephotovoltaic facility 1502 and the sensor facility 1504 may becontinuous, intermittent, wired, wireless, or otherwise configured.

FIG. 16 illustrates a photovoltaic sensor facility 1500 in the presenceof sunlight 1602 according to the principles of the present invention.In embodiments, the photovoltaic sensor facility 1500 may obtain itspower from the sun. In embodiments, the sunlight may be reflectedsunlight, refracted sunlight, direct sunlight, or otherwise directed tothe photovoltaic facility 1500. In embodiments, the light may be aphenomenon that occurs at the nearinfrared, infrared, near uv, uv, orother non-visible radiation.

FIG. 17 illustrates a photovoltaic sensor facility 1500 in the presenceof artificial light 1702 according to the principles of the presentinvention. In embodiments, the photovoltaic sensor facility 1500 mayobtain its power from an artificial light source, such as a light,lighting fixture, incandescent light, halogen light, fluorescent light,HID light, LED light, display, OLED light, plasma light, plasma display,LCD, LCD display, computer display, pda display, mobile phone display,or other facility that generates light.

In embodiments, the photovoltaic may be tuned to a specific wavelength,frequency, bandwidth, and other light spectrum or radiation. Forexample, a uniform, undergarment, blanket, jacket, or other fabric orfacility may be tuned to a particular light source. In embodiments, thetuned spectrum may be used to activate and or power the photovoltaicsystem.

For example, a tuned photovoltaic panel may be mated to specific light,and, when the compatible light is present, the sensor may respondbecause it understands that the light belongs to this panel. Inembodiments, the light is an addressing facility for addressing thisphotovoltaic by tuning between the light source and the photovoltaic. Inembodiments, the tuning is a type of communication protocol. Forexample, to communicate to it wirelessly one transmits at thiswavelength. In embodiments, the addressing scheme is used for security.For example, it may be used to generate a card key. If the user has aphotovoltaic light pulse that is read by the photovoltaic facility, thena light activated lock may open.

FIG. 18 illustrates a photovoltaic sensor facility including aphotovoltaic facility 1502, a sensing facility 1504, and an energystorage facility 1802 according to the principles of the presentinvention. In embodiments, the energy storage facility 1802 storesenergy for the photovoltaic sensing facility. In embodiments, the energystorage facility 1802 is adapted to be connected to the photovoltaicfacility 1502 and or the sensing facility. In embodiments, theconnection may be continuous, intermittent, wired, wireless, orotherwise configured. In embodiments the energy storage facility 1802may be adapted in parallel, series or other connection topology. Inembodiments, the storage facility 1802 stores energy generated by thephotovoltaic facility 1502 or delivers energy to the sensing facility1504, or it may both store and deliver energy. For example, the energystorage facility may be and/or include a battery, chargeable cell,rechargeable cell, energy retention cell, capacitor, capacitancefacility, inductor, inductance facility, hydrogen storage facility,split water facility, electrochemical storage facility, potential energystorage facility, mechanical energy storage (e.g. spring), or otherfacility adapted to store energy. In embodiments, the energy storagefacility 1802 may be a super capacitor. For example, a super capacitormay generate high peak energies, but the photovoltaic facility mayoperate at a lower level.

In embodiments a vending machine is associated with a photovoltaicfacility as described herein. For example, it may be a self-poweredvending machine; it may have a lower power requirement; and/or the powerrequirement may come in discrete bursts. In embodiments, thephotovoltaic facility may be associated with advertising. For example,such a system may be used to know what is on a shelf. In embodiments,the photovoltaic facility may be associated with traceability of aproduct. For example, the system may be employed with an RFID system, orother ID system, including a transmitting ID system, associated with aproduct to trace the product through its life cycle, including throughmanufacturing, distribution, use, and disposal. In embodiments, such aphotovoltaic ID system may be linked to point of purchase. Inembodiments, an ID facility (e.g. RFID, ID transmission, keyed IDtransmission, data enabled ID transmission) may be combined with asensor and or a photovoltaic facility.

FIG. 19 illustrates a photovoltaic sensor facility including aphotovoltaic facility 1502, a sensing facility 1504, and an energyfiltering facility 1902 according to the principles of the presentinvention. In embodiments, the energy filtering facility 1902 filtersenergy, voltage, current, power, or other energy for the photovoltaicsensing facility. In embodiments, the energy filtering facility 1902 isadapted to be connected to the photovoltaic facility 1502 and or thesensing facility. In embodiments, the connection may be continuous,intermittent, wired, wireless, or otherwise configured. In embodiments,the energy filtering facility 1902 may be adapted in parallel, series,or other connection topology. In embodiments, the energy filteringfacility 1902 filters energy generated by the photovoltaic facility 1502and/or delivers filtered energy to the sensing facility 1504. Forexample, the energy filtering facility 1902 may be and/or include acapacitor, capacitance facility, inductor, inductance facility,processor adapted to filter, circuit adapted to filter, transformercircuit, or other facility adapted to filter energy. In embodiments, theenergy filtering facility 1902 is adapted to remove noise from thepower. For example, when the photovoltaic system is powered by light, itis difficult to predict the incoming power quality; the energy filteringfacility 1902 may be adapted to remove noise from the power. Inembodiments, algorithms may be employed (e.g. through a processordescribed below) to predict and or manipulate the power output forbattery charging or power applications. In embodiments, the algorithmsmay use simulations based on the type of photovoltaic facility materialto improve the predictions and regulations.

FIG. 20 illustrates a photovoltaic sensor facility including aphotovoltaic facility 1502, a sensing facility 1504, and an energyregulation facility 2002 according to the principles of the presentinvention. In embodiments, the energy regulation facility 2002 regulatesenergy, voltage, current, power, or other energy for the photovoltaicsensing facility. In embodiments, the energy regulation facility 2002 isadapted to be connected to the photovoltaic facility 1502 and/or thesensing facility. In embodiments, the connection may be continuous,intermittent, wired, wireless, or otherwise configured. In embodiments,the energy regulation facility 2002 may be adapted in parallel, series,or other connection topology. In embodiments, the energy regulationfacility 2002 regulates energy generated by the photovoltaic facility1502 and/or delivers regulated energy to the sensing facility 1504. Forexample, the energy regulation facility 2002 may be and/or include acapacitor, capacitance facility, inductor, inductance facility,processor adapted to regulate, circuit adapted to regulate, transformercircuit, or other facility adapted to filter energy.

FIG. 21 illustrates a photovoltaic sensor facility including aphotovoltaic facility 1502, a sensing facility 1504, an energy storagefacility 1802, and a recharging facility 2102 according to theprinciples of the present invention. In embodiments, the rechargingfacility 2102 is adapted to recharge energy, voltage, current, power, orother energy associated with the photovoltaic sensing facility. Inembodiments, the recharging facility 2102 is adapted to be connected tothe photovoltaic facility 1502, the energy storage facility 1802, and/orthe sensing facility 1504. In embodiments, the connections may becontinuous, intermittent, wired, wireless, or otherwise configured. Inembodiments, the recharging facility 2102 may be adapted in parallel,series, or other connection topology. In embodiments, the rechargingfacility 2102 recharges energy stored by the energy storage facility.For example, the recharging facility 2102 may be and/or include acapacitive recharger, inductive recharger, mechanical recharger,electrical recharger, motion recharger, sensor recharger, or otherrecharging facility. In embodiments, the recharging facility may beadapted to receive power from ac sources, dc sources, photovoltaicsources, rf sources, inductively coupled sources, capacitively coupledsources, or other power sources. In embodiments, the recharging facilityis adapted to receive power from multiple sources.

FIG. 22 illustrates a photovoltaic sensor facility including aphotovoltaic facility 1502, a sensing facility 1504, a processingfacility 2202, a receiving facility 2204, a transmitting facility 2208,and a memory facility 2210 according to the principles of the presentinvention. In embodiments, the processing facility 2202 may processsignals received from external sources and/or process signals from thesensing and/or photovoltaic facilities. In embodiments, the processingfacility 2202 may be associated with a transmitting facility 2208adapted to transmit data, information, signals, and the like. Inembodiments, the processing facility may be associated with a receivingfacility 2204 adapted to receive data, information, signals, and thelike. In embodiments, the processing facility 2202 may be associatedwith a memory facility 2210 adapted to store data, information, signals,and the like. In embodiments, the connections among the severalfacilities may be continuous, intermittent, wired, wireless, orotherwise configured. In embodiments, the facilities may be connected inparallel, series, or other connection topology. In embodiments, theprocessor may be a microprocessor, a circuit, a passive circuit, anactive circuit, or other facility adapted for processing data, signals,information and the like. For example, the receiver may be adapted toreceive an initiation signal to initiate a sensor function in a wirelessor wired fashion. Once the signal is received by the receiving facility,the receiving facility may communicate information, data, a signal, orthe like to the processor, and the processor may initiate a sensingfunction. In embodiments, the transmitter is adapted to transmit asdirected by the processor. For example, the processor may collect datafrom the sensing facility and transmit the data, or indication from thedata, through the transmitter in a wireless or wired fashion. Inembodiments, the processor stores data, information, signals, and/or thelike in the memory facility 2210. For example, the processor may storedata associated with a signal received by the receiving facility, dataassociated with a signal transmitted by the transmitting facility,and/or data gathered from the photovoltaic facility and/or the sensingfacility. For example, the sensing facility may produce data, and theprocessor may store the data in memory. By way of another example, datamay be received that relate to the system, and the processor may saveinformation relating to the received information. The receivedinformation may be calibration information, initiation information,termination information, collection information, or other information.

FIG. 23 illustrates a photovoltaic sensor facility including aphotovoltaic facility 1502, a sensing facility 1504, and an MEMSfacility 2302 according to the principles of the present invention. Inembodiments, the photovoltaic sensor facility may be incorporated with,incorporated onto, and/or associated with an MEMS facility 2302.

FIG. 24 illustrates a photovoltaic sensor facility network 2400according to the principles of the present invention. In embodiments, aphotovoltaic sensor facility(ies) 1500 or a photovoltaic sensor facilityassociated with other facilities (e.g. those facilities described inconnection with FIGS. 15-23) may be associated with a network 2402. Forexample, a plurality of photovoltaic sensor facilities may be adapted tobe connected to a network. The photovoltaic sensors for example mayinclude transmitters and/or addressable controllers. The network may bea local area network, personal area network, wide area network, theInternet, or other network facility. For example, a network oftemperature sensors may be deployed in greenhouses to monitor thetemperature conditions within the greenhouses. In embodiments, thephotovoltaic sensing facilities are tuned to respond to spectra that areassociated with the plants' growth. For example, the particular plantsmay be adapted to respond favorably to blue and red light, and thephotovoltaic sensor facilities may be adapted to respond to blue and/orgreen light. Other useful networking examples include use in militarydrones, automotive networks, buoys, espionage, homeland security,reservoir monitoring, sensitive industrial plants, and nuclear wastemanagement. In embodiments, the photovoltaic sensor facilities mayinclude wireless communication facilities such as Bluetooth, ZigBee, orother personal area technologies.

FIG. 25 illustrates a photovoltaic sensor facility network according tothe principles of the present invention. In embodiments, a photovoltaicsensor facility(ies) 1500, or a photovoltaic sensor facility associatedwith other facilities (e.g. those facilities described in connectionwith FIGS. 15-23) may be associated with a network 2402. For example, aplurality of photovoltaic sensor facilities may be adapted to beconnected to a network. The photovoltaic sensors for example may includetransmitters and/or addressable controllers. The network may be a localarea network, personal area network, wide area network, the Internet, orother network facility. In embodiments, the network 2402 is associatedwith a server 2504 and a client computing facility 2502. In embodiments,the server 2504 may be associated with a database and/or set ofdatabases 2508. For example, the photovoltaic sensing facilities maycommunicate information through a network 2402, and the client computingfacility may collect the information directly and/or through the server2504. The server and/or the client computing facility may be adapted tointeract with the photovoltaic sensing facilities for a number ofactivities. For example, the interaction may initiate acquisition ortermination of a process, collect information relating to the sensedinformation, or collect information relating to a component of thephotovoltaic sensing facility (e.g. an energy storage facilitycondition).

FIG. 26 illustrates a photovoltaic sensor facility network according tothe principles of the present invention. In embodiments, a photovoltaicsensor facility(ies) 1500, or a photovoltaic sensor facility associatedwith other facilities (e.g. those facilities described in connectionwith FIGS. 15-23) may be associated with a network 2402. For example, aplurality of photovoltaic sensor facilities may be adapted to beconnected to a network. In embodiments, photovoltaic sensor facilitiesmay be adapted to connect (e.g. transmit and/or receive) to the networkthrough wired transmission 2602 or wireless transmission 2604.

FIG. 27 illustrates a photovoltaic sensor facility network 2700according to the principles of the present invention. In embodiments, aphotovoltaic sensor facility(ies) 1500, or a photovoltaic sensorfacility associated with other facilities (e.g. those facilitiesdescribed in connection with FIGS. 15-23) may be associated with anetwork 2402. In embodiments, the network 2402 may be a local areanetwork where individual computers 2502 are adapted to communicate viathe network and/or communicate with a server.

FIG. 28 illustrates a photovoltaic sensor facility peer-to-peer network2800 according to the principles of the present invention. Inembodiments, a photovoltaic sensor facility(ies) 1500, or a photovoltaicsensor facility associated with other facilities (e.g. those facilitiesdescribed in connection with FIGS. 15-23) may be associated with apeer-to-peer network 2402.

FIG. 29 illustrates a photovoltaic sensor facility network 2900 whereinthe communication between devices involves the internet according to theprinciples of the present invention. In embodiments, a photovoltaicsensor facility(ies) 1500 or a photovoltaic sensor facility associatedwith other facilities (e.g. those facilities described in connectionwith FIGS. 15-23) may be associated with the internet 2402.

FIG. 30 illustrates a photovoltaic sensor facility array 3002 incommunication with a network 2402 according to the principles of thepresent invention. In embodiments, a photovoltaic sensor facility(ies)1500, or a photovoltaic sensor facility associated with other facilities(e.g. those facilities described in connection with FIGS. 15-23) mayassociated in an array, and the array of photovoltaic sensors may beassociated with the network 2402.

FIG. 31 illustrates several photovoltaic sensor facilities arranged on asensor network 3102 wherein the network of sensors is in communicationwith a computer network 2402 according to the principles of the presentinvention. In embodiments, a photovoltaic sensor facility(ies) 1500, ora photovoltaic sensor facility associated with other facilities (e.g.those facilities described in connection with FIGS. 15-23) mayassociated in an array, through a sensor network, and the array ofphotovoltaic sensors may be associated with the computer network 2402.

An aspect of the present invention relates to photovoltaic variablestructures. In embodiments, variable structures may take the form ofvariable shaped structures. For example, photovoltaic structures may beprovided to allow expansion and contraction to fit a particularapplication, or variable structures may be provided to allow theavailable power to be varied. In embodiments, variable structures maytake the form of folding photovoltaics, flexible photovoltaics,expandable photovoltaics, bendable photovoltaics, shifting structures,and other structures adapted to provide variable structures.

FIGS. 32 A, B, C, and D illustrate several variable photovoltaicstructures according to the principles of the present invention. Forexample, variable structure 3202 illustrates several photovoltaicelements connected through flexible segments. The flexible segments mayallow the structure to be folded, bent, curved, or otherwise shaped tofit a particular device, application, or environment. In embodiments,the flexible segments also provide for variable power, voltage, and/orcurrent delivery from the photovoltaic. For example, if one photovoltaicelement is folded over another, leaving less exposed active surfacearea, the photovoltaic will produce less power, voltage, and/or current.In embodiments, this variable structure provides flexible power controlsuitable to the application, device, and or environment. In embodiments,variable structure photovoltaics include multiple connections, such asvariable structure 3202, and some include single element connections,such as 3204. There are many variations to the methods of connectingelements of the photovoltaic structures, for example parallel, series,or other connections, and the present invention is not limited to anyparticular connection method, and such variants are encompassed by thepresent invention.

Variable structure 3208 (A) has several photovoltaic elements joined atone corner to provide a fan-like variable photovoltaic structure.Variable structure 3208 (B) has several photovoltaic elements connectedtogether by joining a first and second corner of several photovoltaicelements. Variable structure 3210 has several photovoltaic elementsjoined at one corner to provide a fan-like variable photovoltaicstructure with narrow elements or wings. Variable structure 3214illustrates an alternating series connection topology connecting severalphotovoltaic elements. Variable structure 3212 illustrates a compactfoldable photovoltaic system where the photovoltaic elements are closetogether.

FIG. 33 illustrates a variable photovoltaic structure 3300 wherein thevariable photovoltaic structure includes multiple photovoltaic segments3302 connected through electrical segments which can rotate or berotated 3304 and 3308. In embodiments, the photovoltaic segments 3302a-d rotate over one another (e.g. in the indicated direction ofrotation). The electrical connections 3304 and 3308 for the photovoltaicsegments 3302 a-d are adapted to remain in electrical association withthe photovoltaic segments during rotation. For example, electricalconnection 3304 is circular to retain connection with the negative polesof the photovoltaic segments while the segments are rotated, andelectrical segments 3308 are linear and connect with a center rotationalpoint to remain electrically connected with the positive poles of thephotovoltaic segments. It should be appreciated that the presentinvention is not limited to any particular electrical or mechanicalconnection facility, and there are many other electrical connectionsenvisioned and encompassed by the present invention. For example, eachphotovoltaic segment may be connected to positive and negativeelectrical connections, and the several electrical connections may beattached directly or without secondary rotational components. Aconnection facility may also involve capacitive, inductive, or otherelectrical connection facilities. In embodiments, the rotatable segmentsmay be provided for a flexibly shaped photovoltaic facility. Inembodiments, the rotatable segments may be provided to provide avariable power photovoltaic facility. For example, as the photovoltaicsegments are rotated over one another, the exposed surface area may bereduced, and the reduction in exposed surface area may result in reducedpower generation.

FIG. 34 illustrates another variable photovoltaic structure 3400 whereinthe variable photovoltaic structure includes multiple photovoltaicsegments 3302 connected through foldable electrical segments 3304 and3308. In this embodiment, the several segments may be folded over oneanother. In embodiments, the foldable segments may provide a variablepower photovoltaic facility. For example, as the photovoltaic segmentsare folded over one another, the exposed surface area may be reduced,and the reduction in exposed surface area may result in reduced powergeneration.

FIG. 35 illustrates another variable photovoltaic structure 3500 whereinthe variable photovoltaic structure includes multiple photovoltaicsegments 3302 connected through foldable electrical segments 3304 and3308. In this embodiment, the several segments may be folded over oneanother. In embodiments, the foldable segments may provide a variablepower photovoltaic facility. For example, as the photovoltaic segmentsare folded over one another, the exposed surface area may be reduced,and the reduction in exposed surface area may result in reduced powergeneration.

FIG. 36 illustrates several variable photovoltaic structures accordingto the principles of the present invention. In embodiments, the variablephotovoltaic structures may be produced in a number of shapes withvarious sizes. For example, foldable photovoltaic structure 3602includes four foldable photovoltaic segments; foldable photovoltaicstructure 3604 includes seven foldable segments, and foldablephotovoltaic structure 3608 includes ten foldable segments. While theillustrations in FIG. 36 indicate the structures with more segments canbe folded into a smaller footprint, this is not required for allembodiments. For example, a variable photovoltaic structure may includephotovoltaic segments similar in size to those of foldable photovoltaicstructure 3602 but include seven, ten, more or less segments, which whenfolded take up approximately the same footprint of a folded foldablephotovoltaic structure 3602. In embodiments, some or all of the segmentsmay be folded to reduce the footprint and/or reduce the powergeneration. In embodiments, the foldable segments may be arranged toreduce the footprint but retain approximately the original exposedphotovoltaic area to retain the original generation ability. Inembodiments, foldable photovoltaic segments may be folded like a paperairplane, including many variants.

FIG. 37 illustrates a variable photovoltaic structure 3700 with eightfoldable segments 3302. In embodiments, the foldable segments 3302 a-hmay be individually folded, folded in groups, folded as a group, foldedin a forward direction, folded in a reverse direction, partially foldedin a forward direction and partially folded in a reverse direction, orotherwise folded.

FIG. 38 illustrates several variable photovoltaic structures accordingto the principles of the present invention. For example, foldablephotovoltaic structure 3802 may include four eleven inch panels andfully extend to forty-four inches. Foldable photovoltaic structure 3804may include eight eleven-inch panels and fully extend to eighty-eightinches. Foldable photovoltaic structure may include eleven eight-inchsegments and fully extend to eighty-eight inches. In embodiments, thefoldable photovoltaic structures may be fully extended, or fullyunfolded, and/or partially extended.

In embodiments a variable photovoltaic structure may be formed with aprinted flexible circuit as substrate (e.g. in an array). Inembodiments, the photovoltaic segments in the variable photovoltaicstructure may be electrically connected in series or in parallel, acombination of series and parallel connections, or other suitableelectrical connection scheme.

In embodiments, a variable photovoltaic structure may be formed to fitin pockets, on a desk, on a surface, on a device, on a notebookcomputer, or on, in, or around another device. In embodiments, avariable photovoltaic structure may be offered that provides flexibilityin producing certain voltage, current, and/or power based on theflexible layout and/or footprint.

In embodiments, a variable photovoltaic structure may take on a formsimilar to a fan. The structure may be foldable for example, and/or itmay rotate around an axis that lies in the plane of the module. The fanmay rotate outside the plane that the module lies in. The structure mayinclude a central electrical component in which the panels can fan outinto a desired orientation. In embodiments, the electrical connectionsmay be on opposite vertices (e.g. on squares, rectangles, etc). Inembodiments, the variable structure may be optimized for volume storedand/or footprint stored.

In embodiments, a fan may include a preset X dimension (e.g. todetermine voltage) but not have a preset Y dimension, to allow for theoptimization of Y and Z dimensions. That is, trade off one dimension ofa panel versus the thickness of the stack.

In embodiments, square photovoltaic structures are connected at oppositevertices and may have as many as one wants, folded or fanned, and withor without shadowing. In embodiments, the structure may open about a Zaxis; they may stack and then open up around that axis. In embodiments,a stack of cells that is movably disposed about a Z axis is provided.

In embodiments, the photovoltaic structures are provided in a stack butnot connected while in the stack. They can be removed from the stacklike a deck of cards and then reconnected through plugs and/or otherconnection facilitators. The structures may also include clips thatmechanically hold the structures together.

In embodiments, the variable photovoltaic structures are provided in aform similar to a Chinese Fan, and the fan may spread out in angles upto 360 degrees, depending on the structure and/or desired effect. Inembodiments, the fan structure does not use segments that are paralleledged.

In embodiments, a variable photovoltaic structure may be shipped in adeployable format (e.g. stacked up into a package that folds up and isdeployable on removal from the package). For example, if tension isapplied on the two vertices in opposite directions, the structure foldsand unfolds on itself without mechanical intervention. Embodimentsinclude a sensor in a box (e.g. it builds itself out as you open it up).In embodiments, a stack may deploy without breaking, may deploy itself,and may also perform self-orientation.

In embodiments, the variable photovoltaic structure is formed as anaccordion. Not every membrane is supported by a piece of plastic—don'tsupport every piece with injection-molded plastic and piano-type hinges.

In an embodiment, a flexible photovoltaic may have a certain outputunder flex and a different output when not flexed.

An aspect of the present invention involves providing a sensor-feedbacktracking of a light source. In embodiments, a sensor is provided tosense light intensity and a positioning facility (e.g. a motor) may beused to reposition the photovoltaic segment. In embodiments, therepositioning is performed to obtain optimal light intensity exposure,some light intensity exposure, constant light exposure, variable lightexposure, reduced light exposure, or other reason.

FIG. 39 illustrates a variable photovoltaic structure 3900 adapted tosense light and position itself in relation to the light in accordancewith the principles of the present invention. For example, the variablephotovoltaic structure may include a photovoltaic panel 3302, a lightsensor (not shown), and a positioning facility 3902 (e.g. a motor,micro-motor, MEMS motor, servo, rotating member, or movable member), andthe information from the light sensor may be fed back into a processor(not shown). The processor may then adjust the position of thephotovoltaic panel 3302 in relation to the information received from thelight sensor. In embodiments, the panel is movable in one plane, twoplanes, multiple planes, continuous planes, discrete planes, discretepositions, or other suitable positions. In embodiments, the variablephotovoltaic structure 3900 may be adapted to measure light from morethan one light source and adjust its position accordingly.

An aspect of the present invention relates to providing sensors incombination with pv facilities. Illustrative embodiments are describedbelow that include various pv sensor facilities either alone or incombination with other facilities, environments, applications, products,and the like. It is envisioned that each of the below embodiments mayinclude a pv facility described herein above (e.g. those described inconnection with FIGS. 1-7) or other style of pv facility. In addition,each of the below described embodiments may include systems for energystorage, energy filtering, energy regulation, rechargeable pv systems,processors, transmitters, receivers, memory, MEMS facilities, networksand the like as described herein above (e.g. those described inconnection with FIGS. 15-31). For simplification of illustration, eachvariant of the embodiments may not be restated below; however, such withcombinations are envisioned by the applicants and are encompassed by thepresent invention.

FIG. 40 illustrates a flexible photovoltaic facility 4002 (e.g. theflexible photovoltaic facilities associated with FIGS. 32-39) inassociation with a sensor facility 4004.

In embodiments of the invention, an electrical sensor may detect thepresence of electrical inputs such as voltage or current in a device4100 as shown in FIG. 41. In embodiments there may be an indicator 4102in a device. In embodiments the electrical sensor may provide anindication that a device has electrical power and may indicate, forexample, that the device has been turned on, off, or is in sleep mode.In an embodiment the provided indication may be a steady light, ablinking light, a steady sound, a sound with varying intensity orduration, a vibration with varying intensity or duration, or othermethod to alert a user that power is present in the device. Inembodiments the electrical sensor may detect either AC or DC electricalpower of various power, voltage, current, or frequency of various powerlines.

In embodiments, an electrical sensor associated with a photovoltaicfacility may be disposed in a variety of devices to indicate one or moreconditions of the device (such as “on” or “off” status, level of powerconsumption, or the like). Such devices may include computers, monitors,copiers, televisions, radios, CD players, tape players, electronicgames, cell phones, answering machines, automobile dashboard indicators,house power meters, electrical power transformers, stove burners, musicamplifiers, smoke detectors, motion detectors, portable heaters,emergency lighting, cameras, camera flash attachments, electricalrazors, or other devices that may require an indication that electricalpower is present.

In embodiments, home electronic sensors for consumer electronic devices,for example computers, monitors, copiers, televisions, radios, CDplayers, tape players, electronic games, and answering machines, mayhave photovoltaic cells disposed as a film or skin on an exposed surfaceof the device and may use the available lighting within a household.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, automobile indicators may have a photovoltaicfacility, such as film, skin, cell, or other type of facility, on theinterior (e.g. dashboard) or on the exterior (e.g. roof, hood, ortrunk). In embodiments, outdoor devices such as house power meters andelectrical power transformers may have photovoltaic facilities on any ofthe sides of the device for light exposure during any time of the day,or they may have photovoltaic facilities that can be movably pointedtoward a light source as the light source moves. Other devices such asstove burners, music amplifiers, smoke detectors, motion detectors,portable heaters, emergency lighting, cameras, camera flash attachments,and electrical razors may have photovoltaic facilities on the exteriorof the devices as part of the structure of the device and may be able tocharge while in use or when idle. In embodiments, the photovoltaic maybe expandable to allow for an increased surface area when the device isconsuming electricity or increased electric load. In embodiments, theincreased surface area may be manually, automatically, orsemi-automatically achieved. For example, as the device begins to demandmore energy, or predicts it is going to begin to need more energy, thedevice may expand the pv surface area.

In embodiments of the invention, an electrical interference sensor maydetect the presence of electrical power that may create interference toanother circuit as shown in FIG. 42. In embodiments, the electricalinterference sensor (not shown) may detect electrical power interferencefrom power cables, motors, transformers, radio transmitters, variablespeed drives, discharge lighting, or other objects capable of largeelectrical fields. In embodiments, the system may also include anindicator light 4202 indicating interference. While there are manyplaces on a device where the photovoltaic 4204 may be positioned, thedevice of FIG. 42 illustrates a pv on one of the device surfaces. Inembodiments, the electrical interference sensor may provide a visual oraudio signal that indicates interference is present or may providefeedback to a computer or network that a device is affected by anelectrical interference. In embodiments, the device may be capable ofdetermining the type of interference and providing feedback indicatingthe interference type. In embodiments, there may be more than oneelectrical interference sensor in a device or series of devices.

In embodiments, an electrical interference sensor associated with aphotovoltaic facility may be disposed in a variety of devices toindicate electrical interference to a device. In embodiments, suchdevices may include electronic measuring devices (e.g. volt/currentmeters), radios, computers, monitors, printers, faxes, televisions,automobile electronic ignition systems, computer networks (e.g. wired,wireless, or microwave), digital clocks, electronic control systems, orother devices that may be sensitive to external power interference.

In embodiments, home electronic interference sensors such as computers,monitors, printers, faxes, televisions, radios, and digital clocks mayhave photovoltaic cells disposed as a film or skin on an exposed surfaceof the device and may use the available lighting within a household.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, an automobile interference sensor may havephotovoltaic cells disposed as a film or skin on the interior (e.g.dashboard) or exterior (e.g. hood, trunk, or roof). In embodiments,other outside devices such as volt/current meters, electronic controlsystems, or network systems may have photovoltaic cells disposed as askin or film on an exposed surface of the device or may use photovoltaiccells disposed on deployable units that may provide the required amountof power for the electronic interference sensors. The deployable unitsmay unfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Thedeployable photovoltaic facilities may be able to adjust the surface ofunits exposed to a light source manually or automatically. Thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the electronic interferencesensor.

In embodiments of the invention, a voltage sensor may detect thepresence of voltage in a circuit as shown in FIG. 43. In embodiments,the voltage sensor may detect voltage in a circuit and provide feedbackby a visual display of lights, an audio signal, or signal to a computeror network of computers. In embodiments, voltage sensors may be used ina voltage meter, an automobile dashboard display, power generationstations, power sub stations, voltage protection devices,uninterruptible power supplies (UPS), power generators, portable powergenerators, computers, or other devices in which one must know thevoltage in a system. In embodiments, there may be more than one voltagesensor in a device, and voltages may provide feedback to more than onedisplay. In embodiments, the voltage sensor may provide a minimumvoltage, maximum voltage, or display a range of voltages.

In embodiments, devices such as computers, UPS, or voltage meters mayhave photovoltaic cells disposed as a film or skin on an exposed surfaceof the device and may use the available lighting within a household.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. As illustrated in the embodiment of FIG. 43, an automobilevoltage sensor 4302 may have photovoltaic cell(s) 4304 disposed as afilm or skin on the interior (e.g. dashboard) or exterior (e.g. hood,trunk, or roof). Devices such as power stations, power sub stations,power protection devices, power generators, and portable powergenerators may have photovoltaic cells disposed as a skin or film on anexposed surface of the device or may use photovoltaic cells disposed ondeployable units that may provide the required amount of power for thevoltage sensors. The deployable units may unfold, fan out, be stacked inan offset pattern, be positioned on a flat surface, or may be angled totake advantage of a light source. The deployable photovoltaic facilitiesmay be able to adjust the surface of units exposed to a light sourcemanually or automatically. The photovoltaic facilities may be capable ofautomatically tracking a light source to maintain the required power tothe voltage sensor.

In embodiments of the invention, a current sensor may detect thepresence of current in a circuit as shown in FIG. 44. In embodiments,the current sensor 4402 may detect current in a circuit and providefeedback by a visual display of lights, an audio signal, or signal to acomputer or network of computers. In embodiments, current sensors may beused in a current meter, an automobile dashboard display, powergeneration stations, power sub stations, current protection devices,uninterruptible power supplies (UPS), power generators, portable powergenerators, computers, or other devices in which it is required to knowthe current in a system. In embodiments, there may be more than onecurrent sensor in a device and currents may provide feedback to morethan one display. In embodiments, the current sensor may provide aminimum current, maximum current, or display a range of currents.

In embodiments, devices such as computers, UPS, or current meters mayhave photovoltaic cells disposed as a film or skin on an exposed surfaceof the device and may use the available lighting within a household.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, an automobile current sensor may havephotovoltaic cells disposed as a film or skin on a dashboard or surfaceof the hood, trunk, or roof. In embodiments, devices such as powerstations, power sub stations, power protection devices, powergenerators, and portable power generators may have photovoltaic cellsdisposed as a skin or film on an exposed surface of the device or mayuse photovoltaic cells disposed on deployable units that may provide therequired amount of power for the current sensors. In embodiments, thedeployable units may unfold, fan out, be stacked in an offset pattern,be positioned on a flat surface, or may be angled to take advantage of alight source. In embodiments, the deployable photovoltaic facilities maybe able to adjust the number of units exposed to a light source manuallyor automatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the current sensor.

In embodiments of the invention, a resistance sensor may detect theelectronic resistance in a circuit as shown in FIG. 45. In embodiments,the resistance sensor 4502 may detect resistance in a circuit andprovide feedback by a visual display of lights, an audio signal, or asignal to a computer or network of computers. In embodiments, light andaudio signals may increase and decrease in intensity based on theresistance measured by the sensor. In embodiments, resistance sensorsmay be used in a resistance meter, power generation stations, power substations, circuit protection devices, power generators, portable powergenerators, fuse boxes, electrical heating systems, electronic modelingsystems, variable speed controllers, rheostats, or other devices inwhich it is required to know the resistance in a system. In embodiments,the resistance of an electrical system may indicate that an electricalsystem is in an overload state, or the resistance may be controlled toprovide the proper amount of electrical current/voltage to a device. Inembodiments, there may be more than one resistance sensor in a device orsystem and the resistance sensor may provide feedback to more than onedisplay. In embodiments, the resistance sensor may provide a minimumresistance, maximum resistance, or display a range of resistances.

In embodiments, household devices such as fuse boxes, electrical heatingsystems, controllers, switches, thermostats, emergency switches,intercoms, light controls, security systems, security controls,appliances, lights, cabinets, cabinet lighting, windows, doors, walls,ceilings, floors, counters, tools, rheostats and other surfaces may havephotovoltaic cells 4504 (e.g. disposed as a film or skin) on an exposedsurface of the device and may use the available lighting within ahousehold as an energy source. In other embodiments, the householddevice may have the photovoltaic cell disposed within the device and aninternal lighting system may be used as an energy source. For example,the internal system may be used to charge an energy storage cell throughthe use of artificial light and a photovoltaic. In embodiments, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Inembodiments, devices such as power generation stations, power substations, circuit protection devices, power generators, portable powergenerators, electronic modeling systems, and variable speed controllersmay have photovoltaic cells disposed as a skin or film on an exposedsurface of the device or may use photovoltaic cells disposed ondeployable units that may provide the required amount of power for theresistance sensors. In embodiments, the deployable units may unfold, fanout, be stacked in an offset pattern, be positioned on a flat surface,or may be angled to take advantage of a light source. In embodiments,the deployable photovoltaic facilities may be able to adjust the surfacearea exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to the resistancesensor.

In embodiments of the invention, a thermistor sensor may detect thechanges in temperature by increasing/decreasing resistance directlyrelated to the increase/decrease of temperature of an object as shown inFIG. 46. In embodiments, photovoltaic powered thermistor sensor(s) 4602may be used to measure temperatures of fluids or gases. In embodiments,the thermistor sensor may change its resistance based on the temperatureof the object being measured. In embodiments, the resistance may beconverted to a temperature and provide feedback to a computer, network,network of computers, or another circuit.

In embodiments, thermistors may be used in devices such as airconditioners 4604, audio amplifiers, cellular telephones, clothesdryers, computer power supplies, dishwashers, electric blanket controls,electric water heaters, electronic thermometers, fire detectors, homeweather stations, oven temperature controls, pool and spa controls,rechargeable battery packs, refrigerator and freezer temperaturecontrols, small appliance controls, solar collector controls,thermostats, toasters, washing machines, audio amplifiers, automaticclimate controls, coolant sensors, electric coolant fan temperaturecontrols, emission controls, engine block temperature sensors, engineoil temperature sensors, intake air temperature sensors, oil levelsensors, outside air temperature sensor, transmission oil temperaturesensors, water level sensors, blood analysis equipment, blood dialysisequipment, blood oxygenator equipment, clinical fever thermometers,esophageal tubes, infant incubators, internal body temperature monitors,internal temperature sensors, intravenous injection temperatureregulators, myocardial probes, respiration rate measurement equipment,skin temperature monitors, thermodilution catheter probes, commercialvending machines, crystal ovens, fluid flow measurements, gas flowindicators, HVAC equipment, industrial process controls, liquid levelindicators, microwave power measurements, photographic processingequipment, plastic laminating equipment, solar energy equipment, thermalconductivity measurements, thermocouple compensation, thermoplasticmolding equipment, thermostats, water purification equipment, andwelding equipment. In embodiments, devices may use more than onethermistor sensor.

In embodiments, some of the above devices may be portable or handheldand may have photovoltaic cells disposed as a film or skin on an exposedsurface of the device and may use available lighting. Alternatively, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Inembodiments, devices may use a recharging unit with a photovoltaicfacility and then be detached from the photovoltaic facility rechargeunit for use. In embodiments, other devices listed above may be fixed inplace and may have photovoltaic cells disposed as a skin or film on anexposed surface of the device. Photovoltaic cells may be disposed ondeployable units that may provide the required amount of power for thethermistor sensors. The deployable units may unfold, fan out, be stackedin an offset pattern, be positioned on a flat surface, or may be angledto take advantage of a light source. The deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. The photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the thermistor sensor.

In embodiments of the invention, an electrostatic sensor may measure theamount of electrostatic charge on a surface, in an object, or in a fieldbetween charged objects as shown in FIG. 47. In embodiments, thephotovoltaic powered electrostatic sensor 4702 may be able to measurethe electrostatic charge or a change in the charge by direct contactwith the object or by being within the electrostatic charge field. In anembodiment, the electrostatic sensor may provide an output to ameasuring device, computer, computer network, or other device. Inembodiments, the electrostatic sensor may be used for measuring theproper electrostatic charge for painting, testing printed circuit boardconnections, separation of materials (recycling), and security fencingby measuring the change in the electrostatic field by a person orobject. As an example, proper electrostatic painting requires that theproper electrostatic charge be maintained for the proper coating ofpaint. In embodiments, the electrostatic sensor may measure theelectrostatic charge before and during the painting process to assurethe proper painting conditions. In another example, a security fence maybe established by having powered lines establish an electrostatic fieldthat can be measured by an electrostatic sensor. In embodiments, anyobject that enters the electrostatic field may disturb the field, andthe changed field may be measured by the electrostatic sensor. Inembodiments, a person or object may not need to touch the wires tochange the electrostatic field.

In embodiments, devices such as a painting system or security fencedescribed above may have photovoltaic cells which may be disposed ondeployable units that may provide the required amount of power for theelectrostatic sensors. In embodiments, for use in a manufacturingenvironment the photovoltaic facilities may be able to use ambient lightwithin the facility, or the photovoltaic facility may be placed in aremote location that may have adequate lighting. In embodiments, thedeployable units may unfold, fan out, be stacked in an offset pattern,be positioned on a flat surface, or may be angled to take advantage of alight source. In embodiments, the deployable photovoltaic facilities maybe able to adjust the number of units exposed to a light source manuallyor automatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the electrostatic sensor.

In embodiments of the invention, a frequency sensor may measurefrequency created by mechanical or electronic means as shown in FIG. 48.In embodiments, a photovoltaic powered frequency sensor 4802 may be usedto display different frequencies of sound for the purposes of sounddetection (security), sound modulation, frequency adjustment, anddisplay of a frequency for informational needs. In embodiments, thefrequency sensor may provide feedback that may be displayed using analoggauges, light display based on the frequency, or display on a screen asnumbers or a graph. In embodiments, sound is often composed of a numberof frequencies, and there may be more than one frequency sensor todetect and display different frequencies. As an example, a stereo mayhave a display of the various output frequency ranges in the form of acolor display. In embodiments, each frequency range may have a column oflight indicators and may indicate the amplitude of the frequency bydisplay of different colors on the frequency column. Another example maybe a security system that may have a frequency sensor that will “listen”for noise in a room. In embodiments, an indication may be sent to thesecurity system if there is any sound frequency above a certain levelwithin the room. In embodiments, a musical instrument may be tuned witha device using a frequency sensor. In embodiments, the instrument may beplayed, and the tuning device may display the pitch that is played,allowing the instrument to be adjusted to achieve the correct pitch.

In embodiments, devices such as the music tuner or a stereo may beportable or may be household items and may have photovoltaic cellsdisposed as a film or skin on an exposed surface of the device and mayuse available lighting. Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. Devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, other non-portabledevices (e.g. security systems) may have photovoltaic cells disposed asa skin or film on an exposed surface of the device. In embodiments,photovoltaic cells may be disposed on deployable units that may providethe required amount of power for the frequency sensors. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the frequency sensor.

In embodiments of the invention, a temperature sensor may measuretemperature of an object, fluid, gas, or air as shown in FIG. 49. Inembodiments, photovoltaic powered temperature sensors 4902 may be ableto measure the temperature in either analog or digital readings andprovide outputs to both analog and digital displays. In embodiments,temperature sensors may measure a temperature and provide an output to acontroller that may then make adjustments to the amount ofheating/cooling. As an example, a heating unit may allow the setting ofa temperature to maintain in a room. In embodiments, the temperaturesensor may take continual temperature readings and provide an output tothe heating unit. In embodiments, the heating unit logic may thendetermine if the heating of the room should be increased, decreased, orshut off.

In embodiments, temperature sensors may be used in other devices such asair conditioners, manufacturing furnaces, home ovens, automobileenvironmental controls, commercial building environmental controls,automobile engine temperature measurements, environmental emissioncontrol devices, computers, refrigeration controls, weather temperaturemeasurements, medical thermometers, and other devices that requiretemperatures to be maintained to a requirement.

In embodiments, devices such as medical, cooking, and air thermometersmay be portable or handheld and may have photovoltaic cells disposed asa film or skin on an exposed surface of the device and may use availablelighting. Alternatively, a photovoltaic may charge a re-charger for thedevice, where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. Some portable devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, non-portable devicessuch as environmental controls, emission control devices, andmanufacturing furnaces may have photovoltaic cells disposed as a skin orfilm on an exposed surface of the device, or the photovoltaic cells maybe disposed on deployable units that may provide the required amount ofpower for the temperature sensors. In embodiments, the deployable unitsmay unfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Inembodiments, the deployable photovoltaic facilities may be able toadjust the number of units exposed to a light source manually orautomatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the temperature sensor.

In embodiments of the invention, a photovoltaic powered heat sensor maymeasure the heat of an object, fluid, gas, or air as shown in FIG. 50.In embodiments, the photovoltaic powered heat sensor 5002 may not needto touch the object, fluid, gas, or air to measure the heat. Inembodiments, a heat sensor may be directional and may be able to “sense”the heat by being pointed in the direction of the heat. In embodiments,a heat sensor may also be in a device that measures the rate of heatincrease as a security against fire or heat damage. As an example, aheat sensor may be part of a heat detector in a restaurant kitchen. Inembodiments, the restaurant kitchen may normally be hot, and the heatmay fluctuate during the course of the day. In embodiments, a rate ofchange detector with a heat detector may be able to determine when therate of heat change indicates a dangerous fire rather than a normalcooking fire in a kitchen.

In embodiments, heat sensors may also be in devices such as infraredheat detectors for measuring heat loss, in manufacturing furnaces fortemperature control, non-contact temperature devices, home heatdetectors, non-contact mechanical machinery measurement, or othernon-contact heat sensing devices.

In embodiments, devices such as infrared cameras and home heat detectorsmay have photovoltaic cells disposed as a skin or film on an exposedsurface of the device. Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. In embodiments, some portable devices may usea recharging unit with a photovoltaic facility and then be detached fromthe photovoltaic facility recharge unit for use. In embodiments, in anenvironment where there may not be enough ambient light for the properpower generation, such as a manufacturing facility, the photovoltaiccell facility may be located remotely in a location with acceptablelight levels (e.g. outside a window, door, or on a roof). Inembodiments, photovoltaic cells may be disposed on deployable units thatmay provide the required amount of power for the heat sensors. Inembodiments, the deployable units may unfold, fan out, be stacked in anoffset pattern, be positioned on a flat surface, or may be angled totake advantage of a light source. In embodiments, the deployablephotovoltaic facilities may be able to adjust the number of unitsexposed to a light source manually or automatically. In embodiments, thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the heat sensor.

In embodiments of the invention, a photovoltaic powered thermostat 5102may be used in a device to maintain the temperature of a fluid, gas, orair as shown in FIG. 51. In embodiments, thermostats are often used infacilities to provide input to controllers for maintaining a settemperature and determining if the temperature needs to be increased ordecreased. An example is a thermostat in a room; the thermostatcontinuously measures the temperature of the room and sends outputsignals to a controller to maintain the set room temperature. Inembodiments, thermostats may also be used in an automobile to controlthe temperature of the coolant.

In embodiments, thermostats may also be used in devices such as homeovens, commercial ovens, home furnaces, manufacturing furnaces,automobile environmental controls, building environmental controls, hotwater heaters, or other locations that require the maintaining of a settemperature.

In embodiments, devices such as a home, automobile, or other systemthermostat may have photovoltaic cells disposed as a skin or film on anexposed surface of the device. The automobile thermostat may have a skinor film on the automobile interior (e.g. dashboard) or the exterior(e.g. roof, trunk, or hood). Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. In embodiments, in an environment where theremay not be enough ambient light for the proper power generation, such asa manufacturing facility (e.g. commercial ovens, manufacturing furnaces,building environmental controls, and hot water heaters), thephotovoltaic cell facility may be located remotely in a location (e.g.outside a window, door, or on the roof) with acceptable light levels. Inembodiments, photovoltaic cells may be disposed on deployable units thatmay provide the required amount of power for the thermostats. Inembodiments, the deployable units may unfold, fan out, be stacked in anoffset pattern, be positioned on a flat surface, or may be angled totake advantage of a light source. In embodiments, the deployablephotovoltaic facilities may be able to adjust the number of unitsexposed to a light source manually or automatically. In embodiments, thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the thermostat.

In embodiments of the invention, a photovoltaic powered thermometer 5202may be used to measure the temperature of an object, fluid, gas, or airas shown in FIG. 52. In embodiments, a thermometer may be used tomeasure the outside/inside atmospheric temperature, a person'stemperature, manufacturing processes (e.g. photo developers, oils,coating solutions, or plasma coating), automobile air temperaturesinside/outside, automobile engine temperatures, jet engine temperatures,or other objects that require a temperature reading. In embodiments, thethermometer may output the temperature as an analog or digital signal.

In embodiments, devices such as portable thermometers may havephotovoltaic cells disposed as a skin or film on an exposed surface ofthe device. The exposed surface may be an added shape at the end of thethermometer for the photovoltaic skin or film. Alternatively, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Someportable devices may use a recharging unit with a photovoltaic facilityand then be detached from the photovoltaic facility recharge unit foruse. In embodiments, in an environment where there may not be enoughambient light for the proper power generation, such as a commercialfacility (e.g. photo developers, oils, coating solutions, or plasmacoating), the photovoltaic cell facility may be located remotely in alocation (e.g. outside a window, door, or on a roof) with acceptablelight levels. In embodiments, photovoltaic cells may be disposed ondeployable units that may provide the required amount of power for thethermometer. In embodiments, the deployable units may unfold, fan out,be stacked in an offset pattern, be positioned on a flat surface, or maybe angled to take advantage of a light source. In embodiments, thedeployable photovoltaic facilities may be able to adjust the number ofunits exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to thethermometer.

In embodiments of the invention, a photovoltaic powered light sensor5302 may be used to measure the light from a source as shown in FIG. 53.In embodiments the light sensor may measure different light intensityand provide feedback based on the presence of light or the intensity ofthe light, based on a nominal intensity. In embodiments, light sensorsmay be in light switches 5304, garage door safety lights, in automobilesto sense on coming headlights, flame safety sensors, or othersight-sensing devices. In embodiments, light sensors may provide afeedback signal to a computer, computer network, controller, or otherdevice.

In embodiments, devices such as light switches may have photovoltaiccells disposed as a film or skin on an exposed surface of the device andmay use available lighting. Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. In embodiments, devices may use a rechargingunit with a photovoltaic facility and then be detached from thephotovoltaic facility recharge unit for use. In embodiments, otherdevices such as garage door safety lights, automobile headlight sensors,or flame sensors may have photovoltaic cells disposed as a skin or filmon an exposed surface of the device or may be disposed on deployableunits that may provide the required amount of power for the lightsensors. In embodiments, devices such as the garage door safety lightsmay have photovoltaic facilities mounted on the outside of the garagedoor. In embodiments, the automobile headlight sensor may have a film orskin on the interior (e.g. dashboard) or exterior (e.g. roof, hood, ortrunk). In embodiments, the deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. In embodiments, thedeployable photovoltaic facilities may be able to adjust the number ofunits exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to the lightsensor.

In embodiments of the invention, a photovoltaic powered differentiallight sensor 5400 may be used to measure a light source from more thanone location for directional sensing as shown in FIG. 54. Inembodiments, a directional light sensor(s) 5402 may allow for devices torotate or move to point to the light source. In embodiments, deviceswith differential light sensors may be vision-based robotics. Inembodiments, at least two different sensors separated by a distance maysense the light differently depending upon whether the light sensor ispointing at the light source. In embodiments, when the light intensityis the same for the differential light sensors, then the device may bepointing at the light source. In embodiments, differential light sensorsmay be used in manufacturing robotic arms (e.g. to locate an object),independent motion robots, object avoidance devices, auto-focusingdevices, or other devices that require differential light sensing. Inembodiments, the differential light sensor may provide feedback of theintensity of light to a logic circuit, computer, computer network, orcontroller.

In embodiments, devices such as independent motion robots (e.g. robotscapable of independent movement and object avoidance) may havephotovoltaic cells disposed as a film or skin on an exposed surface ofthe device and may use available lighting. Alternatively, a photovoltaicmay charge a re-charger for the device, where the re-charger has aninterface to receive power from the photovoltaic facility and a charginginterface for the device. The device may include an energy storagecapacity, such as a rechargeable battery. In embodiments, devices mayuse a recharging unit with a photovoltaic facility and then be detachedfrom the photovoltaic facility recharge unit for use. In embodiments,other devices in an industrial setting, such as a vision pick and placerobot, may have photovoltaic cells disposed as a skin or film on anexposed surface of the device or may be disposed on deployable unitsthat may provide the required amount of power for the differential lightsensors. In embodiments, the deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. In embodiments, thedeployable photovoltaic facilities may be able to adjust the number ofunits exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to thedifferential light sensors.

In embodiments of the invention, an photovoltaic powered opacity sensor5502 may be used to measure a light intensity as the light is shownthrough a fluid as shown in FIG. 55. In embodiments, the opacity sensormay measure the light 5504 that is or is not absorbed by a fluid 5508over a distance and may measure if the fluid is in a certain state. Inembodiments, the light intensity may be compared to a nominal lightsetting. In embodiments, opacity devices may be a waste water analyzer,oil analyzer, environmental air analyzer, fluid level determinationdevice, or other device to determine if a fluid is in a desiredcondition. In embodiments, the opacity sensor may provide feedback to acontroller, computer, computer network, or logic circuit.

In embodiments, devices such as a fluid level device may determine if afluid is at a max or min level (e.g. automobile washer fluid level, orcoolant level); it may have photovoltaic cells disposed as a film orskin on an exposed surface of the device and may use available lighting.In embodiments, the automobile may have the skin or film on the interior(e.g. dashboard) or exterior (e.g. roof, hood, or trunk). Alternatively,a photovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Inembodiments, devices may use a recharging unit with a photovoltaicfacility and then be detached from the photovoltaic facility rechargeunit for use. In embodiments, other devices such as a waste water, oil,or environmental air analyzer may have photovoltaic cells disposed as askin or film on an exposed surface of the device or may be disposed ondeployable units that may provide the required amount of power for theopacity sensor. In embodiments, the deployable units may unfold, fanout, be stacked in an offset pattern, be positioned on a flat surface,or may be angled to take advantage of a light source. In embodiments,the deployable photovoltaic facilities may be able to adjust the numberof units exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to the opacitysensor.

In embodiments of the invention, a photovoltaic powered scattering lightsensor 5602 may be used to measure a light intensity that may bescattered from a light source through a fluid, gas, or other material5604 as shown in FIG. 56. In embodiments, the scattering light sensormay be offset from a light source as it is shown through a fluid. Inembodiments, the scattering light sensor may measure the light that isscattered by particles in the fluid. In embodiments, the scattered lightmay be compared to a nominal light intensity for the fluid. Inembodiments, scattering light devices may be a waste water analyzer, oilanalyzer, or environmental air analyzer. In embodiments, these devicesmay provide a feed back to a controller, computer, or computer network.

In embodiments, devices such as a waste water, oil, or environmental airanalyzer may have photovoltaic cells disposed as a skin or film on anexposed surface of the device or may be disposed on deployable unitsthat may provide the required amount of power for the scattering lightsensor. In embodiments, the deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. In embodiments, thedeployable photovoltaic facilities may be able to adjust the number ofunits exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to the scatteringlight sensor.

In embodiments of the invention, a photovoltaic powered diffractionalsensor 5702 may be used to measure light diffraction as a light ispassed through a fluid or gas or other material 5704 as shown in FIG.57. In embodiments, a diffractional sensor may measure the diffractedlight from a light source passing through a medium. In embodiments, thediffracted light may provide information such as particle size orinteraction between at least two molecules. In embodiments,diffractional devices may be chemical analyzers, commercial solutionanalyzers, biological or chemical molecular analyzers, or other devicesthat measure particle size. In embodiments, these devices may be used inphoto solution mixers, pharmaceutical material mixers, biologicalresearch, and chemical analysis. In embodiments, feedback from adiffractional sensor may be related to the size of the particle beingmeasured and may be provided to a computer or computer network foranalysis.

In embodiments, devices such as particle size analyzers andmolecular/chemical analyzers may have photovoltaic cells disposed as askin or film on an exposed surface of the device or may be disposed ondeployable units that may provide the required amount of power for thediffractional sensor. In embodiments a particle size analyzer may be aportable device that may work on a fluid sample. In embodiments, theparticle size analyzer may have a skin or film photovoltaic facility ormay use a charging unit for energy storage (e.g. battery). The chargingunit may use photovoltaic facilities to provide power. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the diffractional sensor.

In embodiments of the invention, a photovoltaic powered refractionsensor 5802 may be used to measure the refraction properties of a fluid,gas, or other material to determine the fluid material as shown in FIG.58. In embodiments, the refraction sensor may use a fluid or atmosphericrefraction index for determination of the fluid type. In embodiments,refraction sensor devices may be a handheld computer (PDA) fluidanalyzer, commercial fluid analyzer, pipeline fluid analyzer,atmospheric analyzer, or other device for distinguishing different typesof fluids. In embodiments, the refraction sensors may provide feedbackto computers or a computer network about the refraction index for thefluid. In embodiments, the refraction index may then determine the fluidbeing measured.

In embodiments, devices such as the handheld (e.g. PDA or Pocket PC)fluid analyzer may have photovoltaic cells disposed as a film or skin onan exposed surface of the handheld computer (e.g. PDA or Pocket PC) andmay use available lighting. Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. In embodiments, devices may use a rechargingunit with a photovoltaic facility and then be detached from thephotovoltaic facility recharge unit for use. In embodiments, otherdevices such as a commercial fluid analyzer may have photovoltaic cellsdisposed as a skin or film on an exposed surface of the device or may bedisposed on deployable units that may provide the required amount ofpower for the refraction sensor. In embodiments, the deployable unitsmay unfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Inembodiments, the deployable photovoltaic facilities may be able toadjust the number of units exposed to a light source manually orautomatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the refraction sensor.

In embodiments of the invention, a photovoltaic reflection sensor 5902may be used to determine the location of physical edges, corners, folds,bends or other attributes in objects 5904 through measured reflectedlight 5908 as shown in FIG. 59. In embodiments, reflection sensors maybe used in optical devices for distance measurement or objectidentification by measuring the reflected light on a reflective surface.In embodiments, devices may be used for automotive robotic assembly,robot pick and place devices, quality control measurement devices (e.g.industrial quality control), or other devices for object measurement oridentification. In embodiments, the reflection sensor may providefeedback about the distance to an object or the distance from more thanone surface on an object.

In embodiments, devices such as robotic assembly, robotic pick andplace, and quality control measurements may have photovoltaic cellsdisposed as a film or skin on an exposed surface of the device to powerthe reflection sensor and may use available lighting. Alternatively, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Inembodiments, devices may use a recharging unit with a photovoltaicfacility and then be detached from the photovoltaic facility rechargeunit for use. In embodiments, these devices may have photovoltaic cellsdisposed on deployable units that may provide the required amount ofpower for the reflection sensor. In embodiments, the deployable unitsmay unfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Inembodiments, the deployable photovoltaic facilities may be able toadjust the number of units exposed to a light source manually orautomatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the reflection sensor.

In embodiments of the invention, a photovoltaic polarization sensor 6002may be used to measure the polarization of light 6004 as shown in FIG.60. In embodiments, the polarization sensor may be used to determine ifthe light polarization has decayed over distance and time. Inembodiments, the polarization sensor may measure for tracking purposesthe polarization changes of light reflecting off a moving object. Inembodiments, devices such as those used to track moving objects (e.g.planes, missiles, cars, trains), for fiber optic communication analysis(e.g. break down of signal detection), or other devices for measuringlight polarization may be used. In embodiments, the polarization sensormay provide feedback about the change in the light polarization forfurther calculations by a computer or computer network.

In embodiments, devices such as those used for object tracking or fiberoptic communication (e.g. substations for checking light decay) may havephotovoltaic cells disposed as a film or skin on an exposed surface ofthe device and may use available lighting. In embodiments, objecttracking devices may also be portable devices with photovoltaic cellsdisposed as a film or skin on an exposed surface of the device.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, these devices may havephotovoltaic cells disposed on deployable units that may provide therequired amount of power for the polarization sensor. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the polarization sensor.

In embodiments of the invention, a photovoltaic phase sensor 6102 may beused to determine a phase change of materials from solid/fluid/gas 6104as shown in FIG. 61. In embodiments, the phase sensor may be used toanalyze material phase changes in chemical metering, vapor testing,greenhouse controls, seawater testing, semi volatile chemical stability,gas analysis, chemical “sniffers” for target chemicals, atmosphericsensors, automobile exhaust analyzers, or other devices for sensingmaterial phase changes. In embodiments, the phase sensor may be acontact sensor. In embodiments, the phase sensor may provide feedbackthat indicates the state of the material being tested or measured.

In embodiments, devices such as those used for chemical metering, vaportesting, greenhouse controls, seawater testing, semi volatile chemicalstability analysis, gas analysis, chemical “sniffing” for targetchemicals, atmospheric sensing, or automobile exhaust sensing may havephotovoltaic cells disposed as a film or skin, on an exposed surface ofthe device and may use available lighting. In embodiments, theautomobile exhaust sensor may be part of the automobile and may provideinformation to the automobile control system. The photovoltaic cellsdisposed as a skin or film may be on the interior (e.g. dashboard) orexterior (e.g. hood, roof, or trunk) of the automobile. Alternatively, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Inembodiments, devices may use a recharging unit with a photovoltaicfacility and then be detached from the photovoltaic facility rechargeunit for use. In embodiments, these devices may also have photovoltaiccells disposed on deployable units that may provide the required amountof power for the phase sensor. In embodiments, the deployable units mayunfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Inembodiments, the deployable photovoltaic facilities may be able toadjust the number of units exposed to a light source manually orautomatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the phase sensor.

In embodiments of the invention, a photovoltaic florescence sensor 6202may be used to identify biological materials/organisms based onreflected florescence light 6204 as shown in FIG. 62. In embodiments,florescence sensor devices such as those used for whole/broken grainidentification (e.g. wheat or corn harvesting), seawater/waterbiological testing (e.g. plankton or biological contaminates), orbio-warfare agent detection (e.g. testing or detecting) may be used. Inembodiments, the florescence sensor may provide feedback to a computeror network of computers about the florescence reflective wave length ofthe material/organisms for further analysis.

In embodiments, devices such as seawater/water biological testing (e.g.plankton or biological contaminates), bio-warfare agent detection (e.g.testing or detecting) may be portable and may have photovoltaic cellsdisposed as a film or skin on an exposed surface of the device and mayuse available lighting. Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. In embodiments, devices may use a rechargingunit with a photovoltaic facility and then be detached from thephotovoltaic facility recharge unit for use. In embodiments, devicessuch as those used for whole/broken grain identification (e.g. wheat orcorn harvesting), seawater/water biological testing (e.g. plankton orbiological contaminates), or bio-warfare agent detection (e.g. testingor detecting) may have photovoltaic cells disposed on deployable unitsthat may provide the required amount of power for the florescencesensor. In embodiments, the deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. In embodiments, thedeployable photovoltaic facilities may be able to adjust the number ofunits exposed to a light source manually or automatically. Inembodiments, the photovoltaic facilities may be capable of automaticallytracking a light source to maintain the required power to theflorescence sensor.

In embodiments of the invention, a photovoltaic phosphorescence sensor6302 may be used to identify biological materials/organisms based onlong term emission of light 6304 as shown in FIG. 63. In embodiments, aphosphorescence sensor may detect the presence of biological substancesbased on a long term analysis. In embodiments, phosphorescence sensordevices may be used to determine trace constituents in a sample, analyzechemicals in chromatography (e.g. identification of chemicals in asolution), detect specific constituents in biological systems, remotelysense aspects of the environment (e.g. hydrologic, aquatic, andatmospheric biological testing), or other biological tests. Inembodiments, the phosphorescence sensor may provide feedback to acomputer or computer network about the emission light waves ofbiological objects.

In embodiments, devices such as those for constituent testing, chemicalanalysis in chromatography (e.g. identification of chemicals in asolution), or detection of specific constituents in biological systemsmay be portable and may have photovoltaic cells disposed as a film orskin on an exposed surface of the device and may use available lighting.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, devices such as thoseused for trace constituent testing, chemical analysis in chromatography(e.g. identification of chemicals in a solution), detection of specificconstituents in biological systems, or environmental remote sensing(e.g. hydrologic, aquatic, and atmospheric biological testing) may havephotovoltaic cells disposed on deployable units that may provide therequired amount of power for the phosphorescence sensor. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the phosphorescence sensor.

In embodiments of the invention, an photovoltaic optical activity sensor6402 may be used to measure chemical composition of an object 6404 asshown in FIG. 64. In embodiments, the optical activity sensor may beable to determine chemical composition beneath a surface. Inembodiments, optical activity sensor devices may be used in bio-medicalimaging (e.g. human/animal sub-surface imaging), neural imaging, neuralactivity measurement, or other devices to determine chemical compositionor activity. In embodiments, the optical activity sensor may providefeedback as to the chemical activity of an object.

In embodiments, devices such as biomedical imaging (e.g. human/animalsub-surface imaging), neural imaging, and neural activity measurementmay have photovoltaic cells disposed as a skin or film on an exposedsurface of the device or may be disposed on deployable units that mayprovide the required amount of power for the optical activity sensor. Inembodiments, the deployable units may unfold, fan out, be stacked in anoffset pattern, be positioned on a flat surface, or may be angled totake advantage of a light source. In embodiments, the deployablephotovoltaic facilities may be able to adjust the number of unitsexposed to a light source manually or automatically. In embodiments, thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the optical activity sensor.

In embodiments of the invention, an photovoltaic optical sensory arraymay be used to have a plurality of sensors 6502A, 6502B, and 6502C in anarray for measuring refraction, reflection, polarization, phase,florescence, phosphorescence, and optical activity as shown in FIG. 65.In embodiments, the optical sensor array may be an array of any opticalsensor for providing a plurality of images at a time. In embodiments,optical sensor array devices may be chemical detection devices,biological detection devices, sub-surface imaging devices, or otheroptical array sensor systems as explained previously. In embodiments,these optical array sensors may be portable or handheld devices. Inembodiments, an optical senor array may provide a plurality of imagesfrom the array sensors and may be used in pattern recognition.

In embodiments, devices such as chemical detection devices, biologicaldetection devices, and sub-surface imaging devices may be portable orhandheld and may have photovoltaic cells disposed as a film or skin onan exposed surface of the device and may use available lighting.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, these devices may havephotovoltaic cells disposed on deployable units that may provide therequired amount of power for the optical sensor array. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the optical sensor array.

In embodiments of the invention, a photovoltaic imaging sensor 6602 maybe used in a device that captures light on a grid of small pixels asshown in FIG. 66. In embodiments, imaging sensors may be used in anydevice that captures an image of light. In embodiments, an imagingsensor may be used in digital cameras, digital video cameras, cellphones, PDAs, dual mode digital cameras, automation vision systems,biometric tools for security (e.g. retina, fingerprint, facial, or palmrecognition), video conferencing, security cameras, toys, satellites, orother devices capable of capturing an image.

In embodiments, devices such as digital cameras, digital video cameras,cell phones, PDAs, dual mode digital cameras, biometric tools forsecurity (e.g. retina, fingerprint, facial, or palm recognition), videoconferencing, security cameras, or toys may have photovoltaic cellsdisposed as a film or skin on an exposed surface of the device and mayuse available lighting. The use of photovoltaic cell facilities mayallow these devices to be located at a remote location for longunattended periods. Alternatively, a photovoltaic may charge are-charger for the device, where the re-charger has an interface toreceive power from the photovoltaic facility and a charging interfacefor the device. The device may include an energy storage capacity, suchas a rechargeable battery. In embodiments, devices may use a rechargingunit with a photovoltaic facility and then be detached from thephotovoltaic facility recharge unit for use. In embodiments, devicessuch as automation vision systems, video conferencing, security cameras,or satellites may have photovoltaic cells disposed as a skin or film onan exposed surface of the device or may be disposed on deployable unitsthat may provide the required amount of power for the imaging sensor. Inembodiments, the deployable units may unfold, fan out, be stacked in anoffset pattern, be positioned on a flat surface, or may be angled totake advantage of a light source. In embodiments, the deployablephotovoltaic facilities may be able to adjust the number of unitsexposed to a light source manually or automatically. In embodiments, thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the imaging sensor.

In embodiments of the invention, a photovoltaic micro mirror array maybe an array of small mirrors 6702A, 6702B, 6702C, and 6702D that canindividually reflect light to at least one path for analysis as shown inFIG. 67. In embodiments, the micro mirror array may be able to reflectlight to a plurality of paths for analysis of the light by a pluralityof sensors. In embodiments, micro mirror arrays may be used in devicessuch as telescopes, microscopes, satellites, chemical analyzers, orother devices that allow the analysis of at least one light. Inembodiments, devices using micro mirror arrays may provide reflectedlight to other sensors for analysis.

In embodiments, devices such as telescopes, microscopes, satellites, andchemical analyzers may have photovoltaic cells disposed as a film orskin on an exposed surface of the device and may use available lighting.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, these devices may alsohave photovoltaic cells disposed on deployable units that may providethe required amount of power for the micro mirror array. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the micro mirror array.

In embodiments of the invention, a photovoltaic pixel array 6802 may bean array of pixels 6804 that is capable of capturing at least one lightwavelength as shown in FIG. 68. In embodiments, a pixel array may haveat least one type of pixel capable of collecting a range of lightwavelengths. In embodiments, the pixel array may be able to collectlight from a plurality of light wavelengths in the same array by using aplurality of pixel types and may enable the device to collect aplurality of data in the same instant. In an embodiment, the pixel arraymay be able to collect light from visible to near ultraviolet. Inembodiments, pixel arrays may be used in devices such as telescopes,microscopes, security cameras, or other devices that may need to analyzelight in a plurality of wavelengths at the same time. In embodiments,pixel arrays may provide image data to a processor capable ofinterpreting the pixel information.

In embodiments, devices such as telescopes, microscopes, and securitycameras may have photovoltaic cells disposed as a film or skin on anexposed surface of the device and may use available lighting.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, these devices may havephotovoltaic cells disposed on deployable units that may provide therequired amount of power for the pixel array. In embodiments, thedeployable units may unfold, fan out, be stacked in an offset pattern,be positioned on a flat surface, or may be angled to take advantage of alight source. In embodiments, the deployable photovoltaic facilities maybe able to adjust the number of units exposed to a light source manuallyor automatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the pixel array.

In embodiments of the invention, a photovoltaic rotation sensor 6902 maymeasure rotational torque, angle, speed, acceleration, relative angle,relative speed, and relative acceleration of an object on an axis asshown in FIG. 69. In embodiments, devices with rotation sensors may beable to measure these variables for any device that rotates on an axis.In embodiments, a rotational sensor may be used in devices such asbio-mechanical arms/legs, wheels of a automobile, manufacturingmachinery, rotary engines, CD players, disk drives, or other devicesthat measure rotation around an axis. In embodiments, the rotationsensor may provide feedback of rotational torque, angle, speed,acceleration, relative angle, relative speed, and relative accelerationto a controller, computer, or network of computers for further analysisand possible adjustment.

In embodiments, devices such as wheels of a automobile, CD players, ordisk drives may have photovoltaic cells disposed as a film or skin on anexposed surface of the device and may use available lighting. Inembodiments, devices such as bio-mechanical arms/legs may havephotovoltaic cells disposed as a film, skin, or flexible material on asurface of the device and may use available lighting. In embodiments, asthe bio-mechanical arm/leg moves, the film, skin, or flexible materialmay be exposed to light. In embodiments, the photovoltaic facility maybe part of clothing and may provide power to the bio-mechanical arm/leg.In embodiments, the rotation sensor in the wheel of an automobile mayhave photovoltaic cells disposed as a film or skin on the interior (e.g.dashboard) or exterior (e.g. hood, roof, trunk). Alternatively, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery. Inembodiments, devices may use a recharging unit with a photovoltaicfacility and then be detached from the photovoltaic facility rechargeunit for use. In embodiments, devices such as manufacturing machinery orrotary engines may have photovoltaic cells disposed as a skin or film onan exposed surface of the device or may be disposed on deployable unitsthat may provide the required amount of power for the rotation sensor.In embodiments, the deployable units may unfold, fan out, be stacked inan offset pattern, be positioned on a flat surface, or may be angled totake advantage of a light source. In embodiments, the deployablephotovoltaic facilities may be able to adjust the number of unitsexposed to a light source manually or automatically. In embodiments, thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the rotation sensor.

In embodiments of the invention, a photovoltaic velocity sensor 7002 maymeasure the linear velocity of an object as shown in FIG. 70. Inembodiments, the velocity sensor may use at least one method ofmeasuring velocity. For example, cable extension, magnetic induction,microwave, optical, piezoelectric, radar, strain gauge, or ultrasonicdevices may be used to measure linear speed. In embodiments, velocitysensor devices may be used in automobile speedometers, airplanes,rockets, boats, trains, radar guns, or other devices that measure linearvelocity. In embodiments, velocity sensors may provide velocity feedbackto a controller, display, computer, or network of computers.

In embodiments, devices such as automobile speedometers or radar gunsmay have photovoltaic cells disposed as a film or skin on an exposedsurface of the device and may use available lighting. In embodiments,the velocity sensor for the automobile speedometer may have photovoltaiccells disposed as a film or skin on the interior (e.g. dashboard) orexterior (e.g. hood, roof, trunk). Alternatively, a photovoltaic maycharge a re-charger for the device, where the re-charger has aninterface to receive power from the photovoltaic facility and a charginginterface for the device. The device may include an energy storagecapacity, such as a rechargeable battery. In embodiments, devices mayuse a recharging unit with a photovoltaic facility and then be detachedfrom the photovoltaic facility recharge unit for use. In embodiments,devices such as airplanes, rockets, boats, or trains may havephotovoltaic cells disposed as a skin or film on an exposed surface ofthe device or may be disposed on deployable units that may provide therequired amount of power for the velocity sensor. In embodiments, thedeployable units may unfold, fan out, be stacked in an offset pattern,be positioned on a flat surface, or may be angled to take advantage of alight source. In embodiments, the deployable photovoltaic facilities maybe able to adjust the number of units exposed to a light source manuallyor automatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the velocity sensor.

In embodiments of the invention, an photovoltaic accelerometer 7102 maymeasure the dynamic acceleration of an object as shown in FIG. 71. Inembodiments, an accelerometer may measure one-dimensional motion. Inembodiments, accelerometers may be used in devices such as automobiles,elevators, amusement park rides, seismometers, aircraft, satellites, orother objects that measure acceleration. In embodiments, theaccelerometer may provide feedback to a controller, display, computer,or computer network.

In embodiments, devices such as automobiles, amusement park rides, andseismometers may have photovoltaic cells disposed as a film or skin onan exposed surface of the device and may use available lighting. Inembodiments, the accelerometer for the automobile may have photovoltaiccells disposed as a film or skin on the interior (e.g. dashboard) orexterior (e.g. hood, roof, trunk). Alternatively, a photovoltaic maycharge a re-charger for the device, where the re-charger has aninterface to receive power from the photovoltaic facility and a charginginterface for the device. The device may include an energy storagecapacity, such as a rechargeable battery. In embodiments, devices mayuse a recharging unit with a photovoltaic facility and then be detachedfrom the photovoltaic facility recharge unit for use. In embodiments,devices such as elevators, aircraft, or satellites may have photovoltaiccells disposed as a skin or film on an exposed surface of the device ormay be disposed on deployable units that may provide the required amountof power for the accelerometer. In embodiments, the deployable units mayunfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Inembodiments, the deployable photovoltaic facilities may be able toadjust the number of units exposed to a light source manually orautomatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the accelerometer.

In embodiments of the invention, a photovoltaic inclinometer 7202 maymeasure the inclination of an object in relation to a position as shownin FIG. 72. In embodiments, inclinometers may be used in devices such asantennas, rockets, satellites, dams, slope measurements, tunneling, orother devices that require dynamic inclination measurements. Inembodiments, the inclinometer may provide angle information feedback toa controller, display, computer, or computer network.

In embodiments, devices such as antennas, rockets, satellites, dams,slope measurements, or tunneling may have photovoltaic cells disposed asa skin, film, or flexible material on an exposed surface of the deviceor may be disposed on deployable units that may provide the requiredamount of power for the inclinometer. In embodiments, the deployableunits may unfold, fan out, be stacked in an offset pattern, bepositioned on a flat surface, or may be angled to take advantage of alight source. In embodiments, the deployable photovoltaic facilities maybe able to adjust the number of units exposed to a light source manuallyor automatically. In embodiments, the photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the inclinometer.

In embodiments of the invention, a photovoltaic momentum sensor 7302 maymeasure the linear momentum of an object in relation to a position asshown in FIG. 73. In embodiments, a momentum sensor may measure impactmomentum of one object upon another object. In embodiments, momentumsensors may be in devices such as solar dust collectors, automobiles(e.g. collision detection for air bags), aircraft (e.g. black box datacollectors), or other devices to measure momentum. In embodiments, themomentum sensor may provide momentum feedback to a controller, computer,or computer network.

In embodiments, devices such as solar dust collectors, automobiles (e.g.collision detection for air bags), and aircraft (e.g. black box datacollectors) may have photovoltaic cells disposed as a film or skin on anexposed surface of the device and may use available lighting.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, devices may use a recharging unit with aphotovoltaic facility and then be detached from the photovoltaicfacility recharge unit for use. In embodiments, these devices may alsohave photovoltaic cells disposed on deployable units that may providethe required amount of power for the momentum sensor. In embodiments,the deployable units may unfold, fan out, be stacked in an offsetpattern, be positioned on a flat surface, or may be angled to takeadvantage of a light source. In embodiments, the deployable photovoltaicfacilities may be able to adjust the number of units exposed to a lightsource manually or automatically. In embodiments, the photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the momentum sensor.

FIG. 74 illustrates a photovoltaic facility 7402 in association with anelectrical sensor 7404 and a mechanical sensor 7408. While theillustration depicts a parallel electrical association, the electricalconfiguration may be a series or other style connection. In embodiments,the photovoltaic may be associated with more than two sensor facilities.In embodiments, the photovoltaic facility 7402 may be a photovoltaicfacility as described herein.

FIG. 75 illustrates a photovoltaic facility 7402 in association with anelectrical sensor 7404 and a optical sensor 7502. While the illustrationdepicts a parallel electrical association, the electrical configurationmay be a series or other style connection. In embodiments, thephotovoltaic may be associated with more than two sensor facilities. Inembodiments, the photovoltaic facility 7402 may be a photovoltaicfacility as described herein.

FIG. 76 illustrates a photovoltaic facility 7402 in association with anelectrical sensor 7404 and a biological sensor 7602. While theillustration depicts a parallel electrical association, the electricalconfiguration may be a series or other style connection. In embodiments,the photovoltaic may be associated with more than two sensor facilities.In embodiments, the photovoltaic facility 7402 may be a photovoltaicfacility as described herein.

FIG. 77 illustrates a photovoltaic facility 7402 in association with amechanical sensor 7408 and a optical sensor 7502. While the illustrationdepicts a parallel electrical association, the electrical configurationmay be a series or other style connection. In embodiments, thephotovoltaic may be associated with more than two sensor facilities. Inembodiments, the photovoltaic facility 7402 may be a photovoltaicfacility as described herein.

FIG. 78 illustrates a photovoltaic facility 7402 in association with amechanical sensor 7408 and a biological sensor 7602. While theillustration depicts a parallel electrical association, the electricalconfiguration may be a series or other style connection. In embodiments,the photovoltaic may be associated with more than two sensor facilities.In embodiments, the photovoltaic facility 7402 may be a photovoltaicfacility as described herein.

FIG. 79 illustrates a photovoltaic facility 7402 in association with anoptical sensor 7502 and a biological sensor 7602. While the illustrationdepicts a parallel electrical association, the electrical configurationmay be a series or other style connection. In embodiments, thephotovoltaic may be associated with more than two sensor facilities. Inembodiments, the photovoltaic facility 7402 may be a photovoltaicfacility as described herein.

FIG. 80 illustrates a photovoltaic facility 7402 in association with twoelectrical sensors 7404. While the illustration depicts a parallelelectrical association, the electrical configuration may be a series orother style connection. In embodiments, the photovoltaic may beassociated with more than two sensor facilities. In embodiments, thephotovoltaic facility 7402 may be a photovoltaic facility as describedherein.

FIG. 81 illustrates a photovoltaic facility 7402 in association with twomechanical sensors 7408. While the illustration depicts a parallelelectrical association, the electrical configuration may be a series orother style connection. In embodiments, the photovoltaic may beassociated with more than two sensor facilities. In embodiments, thephotovoltaic facility 7402 may be a photovoltaic facility as describedherein.

FIG. 82A illustrates a photovoltaic facility 7402 in association withtwo optical sensors 7502. While the illustration depicts a parallelelectrical association, the electrical configuration may be a series orother style connection. In embodiments, the photovoltaic may beassociated with more than two sensor facilities. In embodiments, thephotovoltaic facility 7402 may be a photovoltaic facility as describedherein.

FIG. 82B illustrates a photovoltaic facility 7402 in association withtwo biological sensors 7602. While the illustration depicts a parallelelectrical association, the electrical configuration may be a series orother style connection. In embodiments, the photovoltaic may beassociated with more than two sensor facilities. In embodiments, thephotovoltaic facility 7402 may be a photovoltaic facility as describedherein.

FIG. 83 shows a photovoltaic facility associated with printed content8300. As shown in FIG. 83, a flexible photovoltaic facility may beincorporated into a magazine or other printed material. For example,when a reader turns to a page of a magazine containing the photovoltaicfacility, the photovoltaic facility may generate electrical energy fromambient light and apply the electrical energy to power a visual display,such as an advertisement, chart, or other graphic, using light-emittingdiodes, organic light-emitting diodes, or other low-power displaytechnologies suitable for use within a magazine. More generally, thedevice may be used in similar fashion to provide electric-powereddisplays within printed materials such as books, magazines, journals,newspapers, and so on. A photovoltaic facility may be disposed on a foldout page that permits it to be expanded in order to present a largersurface area to the available light source. The device may also, orinstead, be placed on a cover page or back page of a magazine to power avisual display to attract purchasers to the magazine on a newsstand orother resale location. In embodiments, the photovoltaic facility may beprinted onto the page, either simultaneously with the printing of othercontent or before or after printing other content on the page. Inembodiments the photovoltaic facility may be substantially transparent,or it may be transparent to certain desired wavelengths of light, so asto permit viewing of content of selected colors to be viewed,notwithstanding the presence of the photovoltaic facility on the page.In embodiments a development kit may be provided for enabling a contentprovider such as an author, commercial graphics designer, or publisherto associate a photovoltaic facility with an item of printed content,such as any of the items described throughout this disclosure. In oneaspect, there is described herein a method of providing printed materialthat includes associating a photovoltaic facility with printed material,wherein the photovoltaic facility provides energy for an item that isassociated with content of the printed material. The content mayinclude, for example, an advertisement, an informational graphic, or aself-lighted text, and the item may be a lighted or animated displaywithin the content.

FIG. 84 shows a photovoltaic facility associated with a beveragecontainer 8400. As shown in FIG. 84, a photovoltaic facility may beincorporated into a cup, mug, soda bottle, soda can, or other beveragecontainer. The photovoltaic facility may generate electricity fromambient light and be associated with a number of other systems toprovide functions associated with the beverage container. For example,the photovoltaic facility may generate electricity to power athermosensor (such as a thermocouple), processor, and display that sensea temperature of a liquid within the beverage container and display anindication of the temperature. The indication of temperature may be, forexample, an animated thermometer, a display of alphanumeric textindicating degrees such as Celsius or Fahrenheit, a status bar with arange of temperatures (e.g., cold, cool, room temperature, warm, hot),or an alphanumeric display of text indicating suitability of drinkingtemperature of a warm or cool beverage. For perishable beverages such asdairy or fruit juices, the photovoltaic facility may power a sensor thattracks temperature over time and generates a caution indication when thedrink may have spoiled. The photovoltaic facility may also, or instead,generate electrical energy from ambient light and apply the electricalenergy to power a visual display, such as an advertisement, chart, orother graphic, using light-emitting diodes, organic light-emittingdiodes, or other low-power display technologies suitable forincorporation into a grocery item or other consumer good. Thephotovoltaic facility may power a visual display to attract purchasersto the beverage container on a store shelf or other resale location. Thephotovoltaic facility may be printed onto the beverage container, eithersimultaneously with the printing of other content, or before or afterprinting other content on the container. This process may beincorporated into a manufacturing process, such as when graphicalcontent is placed on aluminum sheets that are to be formed into cans. Inembodiments the photovoltaic facility may be substantially transparent,or it may be transparent to certain desired wavelengths of light, so asto permit viewing of content of selected colors to be viewed,notwithstanding the presence of the photovoltaic facility on thebeverage container.

In embodiments a development kit may be provided for enabling a contentprovider such as a beverage maker, commercial graphics designer, orbottling facility to associate a photovoltaic facility with a beveragecontainer, such as any of the items described throughout thisdisclosure. As described above, there is also disclosed herein a methodfor making a beverage container, including associating a photovoltaicfacility with the beverage container and associating the photovoltaicfacility with a display, wherein the photovoltaic facility providespower to the display. The photovoltaic facility may be adhered in partto the beverage container and may fold open to expose a larger surfaceto ambient light to provide additional energy to the display and anyother associated electronics.

FIG. 85 shows a photovoltaic facility incorporated into a “try me”feature of a packaged electrical device 8500. The electrical device maybe a toy, game, instrument, musical device, doll, stuffed animal, and soon. “Try me” features may include buttons to activate audio-visualoutput from the device, or it may include electro-mechanical systemssuch as robotic components, animatronic features, game play, and thelike. For example, the photovoltaic facility 8502 may be incorporatedinto the packaging for the device, such as on a panel or panels of acardboard container. The photovoltaic facility may, for example, providepower from ambient light to recharge a battery or other energy sourceassociated with the device, thus improving the life and availability ofthe “try me” feature. The photovoltaic facility may also provide powerfor advertisements or other active display features as describedgenerally above. In embodiments, the photovoltaic facility may beprinted onto the packaging, either simultaneously with the printing ofother content, or before or after printing other content on the page. Inembodiments the photovoltaic facility may be substantially transparent,or it may be transparent to certain desired wavelengths of light, so asto permit viewing of content of selected colors to be viewed,notwithstanding the presence of the photovoltaic facility on thepackage. In embodiments a development kit may be provided for enabling atoy manufacturer, designer, or marketing professional to associate aphotovoltaic facility with an item of packaging, such as any of theitems described throughout this disclosure. In one aspect, there isdescribed herein a method of providing packaging for an electronicdevice that includes associating a photovoltaic facility with a package,wherein the photovoltaic facility provides energy for an item that isassociated with printed material on the package or an electronic devicecontained within the package. The printed material may include, forexample, an advertisement, an informational graphic, or a self-lightedtext, and the electronic device may include any electronic device thatmight usefully employ a try me feature including, but not limited to,toys, games, instruments, music players, personal electronic devicessuch as electronic organizers or calculators, and so on.

FIG. 86 shows a radio frequency identification (RFID) device 8600printed with a photovoltaic facility. Many RFID cards used in securityapplications and the like are printed with graphics such as corporatelogos, photographs, or other indicia. The printing operation may includea photovoltaic facility for powering the RFID device in, for example,active RFID technology applications. Similarly, security devices thatrequire accurate clocks or other timing devices, such as SecureID cardsthat generate a passcode using a current time and/or a personalidentification number entered by a user, may be powered or recharged bya photovoltaic facility printed on a surface thereof. Still moregenerally, any product may be printed with one or more photovoltaicfacilities on an exterior surface to capture electrical energy fromambient light. The energy may be used generally for recharging a batteryor other energy source associated with the device or to provide electricpowered displays on the device using, for example, the light emittingdiodes, organic light emitting diodes, or other low-power displaytechnologies. In the RFID example provided above, a method offabricating an RFID device may include printing a photovoltaic facilityon a surface thereof and associating the photovoltaic facility with anenergy source within the RFID device.

FIG. 87 shows a portable power source 8700 using one or morephotovoltaic facilities. In general a portable power source may includea case with photovoltaic facilities that may be deployed therefrom, suchas by unrolling or unfolding a number of panels of photovoltaicfacilities from the portable power source. In other embodiments, anexpanding frame may be provided for the photovoltaic facility, such asan umbrella structure, a portable movie screen structure, a fan oraccordion structure, a tent or tarpaulin structure, or a spring-loadedroll within a case for the portable power source. The photovoltaicfacilities may be connected to the case and/or separate from the case(with electrical connectors for coupling the photovoltaic facilities tothe case and/or power supply).

The case may be a suitcase, backpack, valise, crate, or other portableor semi-portable device, depending in part upon the amount of electricalenergy desired therefrom. The case may also include one or morebatteries or other energy storage devices that store or buffer unusedpower from the photovoltaic facilities. In addition, any number of powerconversion systems may be incorporated into the case. Thus, for example,using techniques known to those of ordinary skill in the art, electricaloutput from the deployed photovoltaic facility may be provided as 110VAC power, 220V AC power, 12V DC power, 5V DC power, or electrical powerin any other delivery form, including, for example three-phase power orhigh-frequency AC output. The case may also include any number ofoutlets conforming to various industrial standards or local practices,and it may include a control panel for selecting among outputs, such asswitching between 110V and 220V. Control circuitry may also provide userfeedback, such as by indicating when more photovoltaic facilities areneeded to maintain a desired output or battery charge. In certainembodiments, stacks of photovoltaic facilities may be employed tocapture energy from different wavelengths of incident light, providedthe photovoltaic facilities are selected to pass wavelengths forunderlying photovoltaic facilities.

FIG. 88 shows a portable power supply for a computer 8800. A portablecomputer such as a laptop is typically carried in a computer case thatprovides, for example, cushioning to protect the computer and a numberof pockets for carrying computer accessories, documents, and so forth.One or more photovoltaic facilities may be conveniently and usefullyintegrated into such a computer case to extend battery charge for astored computer contained therein. The photovoltaic facility may beprovided, for example, on a spring-loaded roll that may be withdrawnfrom a pocket in the computer case. A photovoltaic facility may also, orinstead, be folded and fit into a pocket of the computer case, with anelectrical connection coupling the photovoltaic facility to a powerconversion system within the computer case. The power conversion systemmay include an inverter for generating 110 V or other alternatingcurrent output from the electrical energy provided by the photovoltaicfacility. In such an embodiment, the computer case may include aconventional 110 V electrical outlet. In other embodiments, the powerconversion system may provide direct DC output for coupling to anelectrical input of the computer, typically 5V DC or 12V DC. While anenergy storage system such as a battery may also be included in thecomputer case, it will be appreciated that this component may be readilyomitted because a laptop or portable computer typically includes its ownbattery. However, in one embodiment, the power conversion system mayrecharge a spare battery for the computer stored within the case.

With sufficient ambient light and or sufficient surface area of thephotovoltaic facilities, the photovoltaic facilities may power acomputer without drawing down the charge in the computer's battery. Inone embodiment, the computer case may include a visually displayed powermeter that indicates what portion of the computer's electricalrequirements are being met by the photovoltaic facility. A user may thusincrease the number or surface area of photovoltaic facilities (limitedin one sense by the physical space available to the user) until all ofthe energy requirements are being met by the photovoltaic facilities.Even where all requirements cannot be met, the photovoltaic facilitiesmay significantly increase the operating life of a charged battery. Inother embodiments, additional photovoltaic facilities may be integratedinto exterior surfaces of the computer case or exterior surfaces of thecomputer itself.

While the computer case described above is one useful application of thesystems described herein, it will be appreciated that numerous otherportable electronic devices can benefit from similar cases includingphotovoltaic facilities. Thus, for example, like cases may be providedfor portable televisions, portable radios, portable CD players, portableDVD players, lightweight and/or portable computer printers, and so on.

FIG. 89 shows a photovoltaic facility in a perishable goods monitoringsystem 8900. The system may be integrated into, for example, individualpackages or items of perishable goods or into crates or other containers8902 designed for transporting and storage of larger quantities of thegoods. In one embodiment, the photovoltaic facility 8904 may maintainpower, or charge, on an energy storage device such as a battery, foroperation of a timer or clock that tracks an approaching expirationdate. The perishable goods monitoring system may include othercomponents in various combinations, such as a processor, a radiofrequency communications system, a display (e.g., for displaying statusinformation), and one or more sensors, to provide varying types ofmonitoring. For example, the system may communicate with an externalsource of time using, for example, radio frequency communications whenambient light is available and the photovoltaic facility can provideelectricity. In such embodiments, the system may power on in response toambient light, retrieve remote time information, determine using theprocessor whether expiration has occurred, and generate a display of thestatus of the items being monitored. The display may include any visualdisplay including liquid crystal displays, light-emitting diodes,organic light-emitting diodes, or other low-power display technologies,as well as any other display technologies. The visual display mayinclude literal information, such as days until expiration, analyticalinformation derived from the literal information such as textualdescriptions (e.g., “good”, “bad”, or “questionable”), or metaphoricalinformation, such as a green light/yellow light/red light display. Inother embodiments, a sensor, such as a temperature sensor, humiditysensor, pressure sensor, motion sensor, and/or ultraviolet light sensormay track environmental conditions of the perishable goods over a periodof time and generate an appropriate display when the goods have spoiledor are at risk of spoiling. Such systems may be particularly useful inoutdoor cargo areas where goods may be stored for an extended period. Inone embodiment, such systems include a battery that is recharged by thephotovoltaic facilities whenever ambient light is available.

FIG. 89A shows a photovoltaic facility 8952 integrated into a portablecooler 8950. The portable cooler may include an insulated container andan electric cooling device. The cooler may also include one or morephotovoltaic facilities that may be deployed by a user to provideelectrical power to the cooling device. For example, one or more sleevesor pockets may be disposed on vertical exterior surfaces of the coolerfor holding folded photovoltaic facilities. The photovoltaic facilitiesmay be removed and unfolded to expose them to ambient light. Whilefolding is not necessary for operation of the portable cooler, it willbe readily appreciated that a greater surface area, and thus more energycapture, may be achieved by a photovoltaic facility that unfolds over alarger area. Similarly, the photovoltaic facilities may be rolled intotubes integrated into sides of the cooler or provided as a separateaccessory that plugs into the portable cooler. In other embodiments, anexpanding frame may be provided for one or more of the photovoltaicfacilities, such as an umbrella structure, a portable movie screenstructure, a fan or accordion structure, a tent or tarpaulin structure,or a spring-loaded roll within a case for the portable power source.Additionally, any of the other folded, rolled, or otherwise segmented orcompacted structures described herein may be usefully employed with theportable cooler described herein to provide a densely packed, portablephotovoltaic facility that can be deployed into a large-surface areastructure. A battery or other energy storage device may be included toprovide additional electrical energy for cooling and/or to capturesurplus electrical energy generated by the photovoltaic facilities. Acontroller may be included to manage battery life and or cooling. Thecontroller may, for example, monitor charge on the energy storage deviceand electrical energy being generated by the photovoltaic facilities andmay permit a user to select cooling profiles such as maximum cooling,maximum battery life, a certain duration of active cooling, orcombinations of these.

FIG. 90 shows an agricultural or farm monitoring system 9000 using aphotovoltaic facility 9002. The system may be housed in a weather-tightcontainer for protection of individual components. In one embodiment,the photovoltaic facility may maintain power, or charge, on an energystorage device such as a battery, for operation of the system. Theagricultural monitoring system may include other components in variouscombinations to provide various types of monitoring, such as aprocessor, a radio frequency communications system, a display (e.g., fordisplaying status information), and one or more humidity sensors, soilsensors, light sensors, or other sensors for monitoring an agriculturalenvironment. For example, the system may include a radio frequencycommunication system for communicating, for example, with an externalsource of time when ambient light is available and the photovoltaicfacility can provide electricity. The system may also use such a radiofrequency communication system to convey monitoring and statusinformation, and it may participate in a network of such monitoringsystems deployed throughout an agricultural and/or farming environment.The network may carry control information based on measurements of themonitoring system, such as by activating a sprinkler system in an areato address dry soil. In some embodiments, the system may power on inresponse to ambient light, take measurements, and transmit sensor data.A display may be provided for display of the status of items beingmonitored. The display may include any visual display including liquidcrystal displays, light-emitting diodes, organic light-emitting diodes,or other low-power display technologies, as well as any other displaytechnologies. The visual display may include literal information, suchas inches of rainfall, analytical information derived from the literalinformation such as textual descriptions (e.g., “dry”, “moist”,“acidic”, and so forth), or metaphorical information, such as an imageof a plant showing relative health.

Various sensors may be included in such a monitoring system. Forexample, moisture sensors may be used to detect soil moisture at varioussoil depths. Sensors may also detect soil nutrients, insectinfestations, sunlight, temperature, air humidity, and any other factorsthat may affect plant growth and health, or it may suggest specificresponsive measures. In one embodiment, the monitoring system mayinclude a battery that is recharged by the photovoltaic facilitieswhenever ambient light is available. A number of such systems may bedeployed in an agricultural or farming environment, and foldable,rollable, or otherwise collapsible photovoltaic facilities may beprovided for convenient set-up, take-down, and redeployment of eachmonitoring system.

FIG. 91 shows a power supply system for a sports venue 9100 using aphotovoltaic facility 9102. Opaque, transparent, or translucentphotovoltaic facilities may be usefully deployed over sporting venues,either as a shade or on top of a closed structure such as a tent, dome,indoor arena, or the like. Such a covering may serve a dual purpose ofproviding shade and electrical power, or it may simply serve as a powersource for an arena. Electricity generated by an area of photovoltaicfacilities may be stored and used, for example, to provide electricityfor lighting, public address systems, signs, scoreboards, concessionstands, and so on while a game or event is in progress. Thus there isdisclosed herein a sports venue covering that provides electricalenergy. A power conversion system may be included to convert resultingelectrical energy into any suitable, useable form. An energy storagedevice may also be included to capture excess electrical energy forlater use.

FIG. 92 shows a power supply system for an outdoor working environmentusing a photovoltaic facility 9200. In certain environments, such ascigar tobacco farms, tobacco may be shaded before use as a cigarwrapper. In such environments, opaque photovoltaic facilities may beusefully deployed as tents, awnings, or other coverings or shades toserve a dual purpose of providing shade and electrical power. Moregenerally, in warm sunny environments, opaque photovoltaic facilitiesmay be used to simultaneously provide shade and generate electricalpower. The electrical power may be used for functions ancillary toshading, such as operation of fans, air conditioners, or other activecooling devices, or simply as a source of electrical power. Thus thereis disclosed herein a sunshade that provides electrical energy. A powerconversion system may be included to convert resulting electrical energyinto any suitable, useable form. An energy storage device may also beincluded to capture excess electrical energy for later use.

FIG. 93 shows a power supply system integrated with an outdoor coveringmaterial 9300. In certain environments, such as dumps, recycling ortransfer stations, landfills, and the like, large areas of ground ormounds of material may be periodically covered, so as to shield againstrain or sun. For example, piles of salt used to de-ice roadways aretypically heaped in covered areas to avoid saturation while not in use.In such environments, large sheets of photovoltaic facilities may beusefully deployed as tents, awnings, or other coverings to serve a dualpurpose of providing shielding from the elements and generatingelectrical power. In sunny environments, these photovoltaic facilitiesmay be used to provide substantial electrical power, which may be storedor used in any desired manner. A power conversion system may be includedto convert resulting electrical energy into any suitable, useable form.An energy storage device may also be included to capture excesselectrical energy for later use.

In embodiments, a photovoltaic facility may be fashioned in a natural orstylized appearance of a leaf of a plant, forming a photovoltaic leaf9400, as illustrated in FIG. 94. The photovoltaic facility may besubstantially transparent, or it may be transparent to certain desiredwavelengths of light, so as to permit viewing of a particular color of asubstrate associated with the photovoltaic facility. For example,without limitation, the substrate may be a flexible facility and may bethe color green, providing for a natural, leaf-like appearance. In thisexample, the photovoltaic facility may be both disposed on the substrateand transparent to the color green, providing for a photovoltaic leafwith natural, leaf-like appearance. An electrical conduit facility maybe fashioned in a natural or stylized appearance of a stem, trunk, orstalk of the plant, forming a conductive core. The photovoltaic leaf maybe physically connected to the conductive core, providing a photovoltaicplant. The photovoltaic plant may be associated with a rechargeablebattery. In some embodiments, the photovoltaic plant may furthercomprise a plurality of photovoltaic leaves connected to the conductivecore. In other embodiments, the photovoltaic plant may yet furthercomprise a plurality of conductive cores connected to each other invarious configurations, providing a natural or stylized branchingappearance. The photoelectric plant may be disposed in hostile territoryas a covert power source for a sensor associated with the photoelectricplant. The photoelectric plant may, in another embodiment, be disposedin a garden as a camouflaged power source to a sensor associated withthe garden, such as a soil moisture sensor. In yet another embodiment,the photoelectric plant may be associated with a light. In thisembodiment, the photoelectric plant may charge the rechargeable batterywhen incoming light allows and may illuminate an area from time to time.Alternatively, the photoelectric plant may provide an entertaininglighting effect from time to time. Other applications of thephotoelectric plant will be apparent from the preceding discussion.

In embodiments, a first photovoltaic facility may be disposed on aflexible facility 9500 in a configuration that may provide a variablecurrent or voltage, as illustrated in FIG. 95. The variability of acurrent or a voltage provided by the photovoltaic facility may dependupon the degree to which the flexible facility is flexed. Thisvariability of the current or voltage may comprise an electrical outputthat may be associated with the degree to which the flexible facility isflexed. Given a physical nature of the photovoltaic facility, which isdescribed elsewhere herein, the electrical output may also be directlyproportional to the intensity of light shining on the photovoltaicfacility. As the object of the present invention may be to detect onlythe degree to which the flexible facility is flexed, this method mayfurther provide a normalized value associated only with the degree towhich the flexible facility is flexed. This aspect of the method maycomprise a second photovoltaic facility that may be disposed on theflexible facility. The second photovoltaic facility may be configured toprovide a reference electrical output that may not significantly dependupon the degree to which the flexible facility is flexed. The electricaloutput and the reference electrical output may be provided to anormalizing facility, which may comprise an integrated circuit, ananalog circuit, or a digital circuit. The normalizing facility mayprovide an output that may be associated with a normalized value thatmay be associated with the degree to which flexible facility is flexed.Alternatively, the first photovoltaic facility may be disposed on aflexible facility in a configuration that may provide a binary currentor voltage that may transition between logical states as the flexiblefacility is flexed beyond a first degree of flex or as the flexiblefacility is relaxed beyond a second particular degree of flex. In oneapplication, the electrical output is associated with a collisiondetection facility on a mobile robot. In another application theelectrical output is associated with a flexing body motion of a personwearing an item of clothing instrumented with the flexible facility.

In embodiments, a photovoltaic facility 9602 may be associated with ananoscale cantilever sensor 9604, which may comprise a piezoresistivecantilever providing an electrical output. One such embodiment isillustrated in FIG. 96. The sensor, by its nature, may be a low-powerdevice and may receive power from the photovoltaic facility. Thephotovoltaic facility and nanoscale cantilever sensor may be disposed ona flexible facility, a rigid facility, a rollout facility, a fold-outfacility, or any other suitable facility. In one application, thenanoscale cantilever sensor may be used to detect a trace level of abiomolecule, for example by associating the electrical output with thedrag through a solution of a biomolecule attached to a functionalizedsurface of the cantilever. In another embodiment, the nanoscalecantilever may provide a sensor output that is associated with tinychanges in a surface stress of the facility onto which the nanoscalecantilever sensor is disposed. In yet another embodiment, the nanoscalecantilever sensor may comprise a nanometer-size magnetic tip providingfor the detection of an individual electron buried below a surface of asample. In still yet another embodiment, the nanoscale cantilever sensormay be coated with a DNA probe associated with a specific protein,providing a site to which the specific protein may bind and cause thecantilever to flex, resulting in a change in the electrical output.Other applications of nanoscale cantilever sensors are known in the artor will be apparent from this discussion.

In embodiments, a photovoltaic facility may have a shape and anorientation that allows for outdoor power generation provided anyinclination of the sun. One such embodiment is illustrated in FIG. 97.In one embodiment, the photovoltaic facility may be a sphere 9702 withan arbitrary orientation. In another embodiment, the photovoltaicfacility may be a cone with the base of the cone oriented toward thesurface of the Earth. In yet another embodiment, the photovoltaicfacility may be a lampshade with the base of the lampshade orientedtoward the surface of the Earth. In still yet another embodiment, thephotovoltaic facility may be a cylinder with a base of the cylinderoriented toward the surface of the Earth. The surface of the Earth maycomprise any form of land or water. In one application, the photovoltaicfacility comprises a package capable of being airdropped. In thisapplication, the package is designed to provide the orientation, asspecified above, upon reaching the surface of the Earth. For example,without limitation, the center of gravity of the package may be disposedtoward the base of the package; the aerodynamics of the package may besuch that the package is likely to impact the Earth at the orientation;and/or the package may eject or otherwise deploy the photovoltaicfacility after impacting the surface of the Earth, where the ejection ordeployment may be designed to provide the photovoltaic facility with theorientation. In another application, the photovoltaic facility comprisesa buoy. In this application, the buoy may contain ballast to provide thephotovoltaic facility with the orientation, which may be subject to avarying offset due to winds and waves. In all applications, the purposeof the photovoltaic facility may be to charge a battery and/or power asensor.

In embodiments, a photovoltaic fiber may be woven into a fabric 9802.One such embodiment is illustrated in FIG. 98. Other such embodimentsare illustrated in FIG. 98A and FIG. 98B This fabric, then, is aphotovoltaic fabric that may be incorporated into a garment, such as amilitary uniform. Alternatively, the photovoltaic fabric may beincorporated into a drapery, rug, blind, or other fabric object used toadorn the interior of a building. Generally, the photovoltaic fabric maybe incorporated into any object normally or optionally containingfabric. In any case, one purpose for including the photovoltaic fiberinto a fabric may be to allow the fabric to charge a battery. Forexample, in one application, it may be desirable to charge a smallbattery that powers a covert camera: Certain espionage scenarios may notallow the installation of a power cable and may require more energy thanmay be stored by any practicable small, single charge battery. Thecovert camera, in this example and without limitation, may be disposedin a room wherein the drapery in the room comprises the photovoltaicfabric. By connecting the photovoltaic fabric to the covert camera andsmall battery, it may be possible to power the covert camera for a timesignificantly longer than is possible with a small, single chargebattery. For another example, in a second application, it may bedesirable for a dismounted soldier to be outfitted with a sensorcomprising, without limitation, a biometric sensor. In this case, thesensor may be powered by a photovoltaic fabric and the fabric may forthe soldier's uniform. Other embodiments will be apparent from thepreceding description.

In embodiments, a photovoltaic facility may be associated with a sensornode 9902A, 9902B, and 9902C, which may receive power from thephotovoltaic facility. One such embodiment is illustrated in FIG. 99.The sensor node may be associated with other sensor nodes in a sensornetwork. The sensor network may comprise a communication facility, whichmay be wired or wireless. In the case that the communication facility iswireless, it may comprise an infrastructure including an access point ormay comprise a point-to-point, ad hoc network. The sensor node may beairdropped into place, hand placed, or autonomously placed by anautomaton such as a robot. In one embodiment, the purpose of the sensornetwork is to monitor an area for troops or machinery. In this case, thesensor node may comprise a microphone or microphone array, a visiblecamera, an infrared camera, a compass, a magnetometer, a seismometer,and/or a global positioning system facility. The sensor node may furthercomprise a data processing facility capable of classifying and/orestablishing a bearing to a detected target of interest. In one example,the detected target of interest may be a tank. The tank may be idling,unseen, under foliage. The sensor node may share the classification andbearing information via the communication facility to the rest of thesensor network. Through a process, such as triangulation, the network ofsensors may establish a geographic fix on the tank and track itsprogress through the sensor array. Other examples should be clear fromthis example. In any case, the photovoltaic facility may be disposed onthe sensor node or may be tethered to the sensor node via a conductivewire.

In embodiments, a photovoltaic facility may be associated with anaccumulator 10002. The accumulator may provide a cumulative output valueassociated with the quantity of light received by the photovoltaicfacility. One such embodiment is illustrated in FIG. 100. Thephotovoltaic facility may be sensitive to one select wavelength, forexample and without limitation UVA or UVB. In one embodiment, thecumulative output value is provided to a display facility, which may bepowered by the photovoltaic facility. The display facility may be aliquid crystal display, a light emitting diode display, an organic lightemitting diode display, a flexible organic light emitting diode display,a projection display, a holographic display, or any other practicabledisplay. In another embodiment, the cumulative output value is providedto an alarm facility that issues an alarm when the cumulative outputvalue reaches a particular value. The alarm may be visual, aural,tactile (such as a vibration), or any other suitable alarm. In yetanother embodiment, the cumulative output value is provided to anexternal computing facility that may store, process, and/or forward thecumulative output value. The computing facility may be an applicationand/or database server that is part of a three-tier Web system thatpresents information associated with the cumulative output value to aperson via a user interface rendered by a Web browser. In allembodiments, the photovoltaic facility associated with the accumulatormay provide a warning facility to the person who is being exposed topotentially hazardous levels of sunlight. The warning facility maymeasure the quantity of harmful rays impacting an area associated with aperson and may issue an indication of the measured quantity and/or mayissue an alarm when the measured quantity exceeds a limit quantity. Thewarning facility may be disposed on an adhesive strip, which may beaffixed to the person or an item of the person's clothing. In anotherembodiment, the warning system may be an integral part of a hat or otheritem of the person's clothing that is likely to be exposed to sunlight.Other embodiments of the warning facility will be apparent from thepreceding discussion.

FIG. 101 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments a sensor may detectone or more of smoke, fire, and heat 10102. Such a sensor may beassociated with a photovoltaic facility which may directly or indirectlyact as an energy source for such sensor in any of the variousconfigurations described throughout this disclosure. The smoke, fire,and/or heat sensor may be located in a home environment, a non-homeenvironment, an industrial environment, a factory, and/or a workplace.The smoke, fire, and/or heat sensor may be mobile and capable offunctioning in a vehicle, such as an automobile, a truck, a recreationalvehicle, an airplane, a helicopter, a blimp, a boat, or a hovercraft.The smoke, fire, and/or heat sensor may monitor an environment occupiedby humans, such as the cabin of an aircraft or the floor of a factory.The smoke, fire, and/or heat sensor may monitor an environment notnormally occupied by humans, such as a fuel tank or engine compartment.The smoke, fire, and/or heat sensor may be part of a network of smoke,fire, and/or heat sensors or other sensors. The network of sensors mayenable the monitoring of large areas. The network of sensors may feedinformation to one or more central points on the network.

The smoke sensor may sense particles in the air or may react toobstruction of light sources as a result of smoke. The sensor may relyon algorithms to distinguish light obstructions attributable to smokefrom those attributable to other sources. The fire sensor may detectlight of certain wavelengths or flicker frequency known to beattributable to fire. The heat detector may respond to changes intemperature in a given area or in the rate of change of the temperaturein a given area.

The smoke, fire, and/or heat sensor and associated photovoltaic facilitymay comprise a single unit which may be portable. The unit may bemountable on any number of surfaces through the use of adhesives,magnets, suction cups, screws, and fasteners. An individual or team maycarry a single unit with them for the duration of a project or activity.For example a surface mineral exploration crew could equip theirhelicopter with a unit. The unit could then be transferred to the busused to transport the crew to their campsite. The campsite could then beoutfitted with the unit in order to provide monitoring while the crewsleeps.

FIG. 102 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments a sensor may detectthe presence, absence, and/or one or more characteristics of a vaporand/or gas 10202. Such a sensor may be associated with a photovoltaicfacility which may directly or indirectly act as an energy source forsuch a sensor in any of the various configurations described throughoutthis disclosure. Certain characteristics of a vapor and/or gas that asensor may detect and/or measure may include composition, moisturelevel, pressure, temperature, direction, speed, dispersion, density,reactivity, inertness, acidity, concentration, and source.

In other embodiments a vapor and/or gas may be channeled over thephotovoltaic facility. The vapor and/or gas may serve to concentratelight or light of a certain wavelength. A sensor powered by thephotovoltaic facility may function in a feedback loop to assist withoptimizing the flow and concentration of the vapor and/or gas so as tomaximize the energy generated by the photovoltaic facility.

The vapor and/or gas sensor coupled with the photovoltaic facility mayalso be attached to a weather balloon. The sensor may measure certaincharacteristics of atmospheric vapors and/or gases for meteorologicalpurposes. The sensor and photovoltaic apparatus may include a batterycapable of being recharged by the photovoltaic facility so as to enablemonitoring in low light conditions. The vapor and/or gas sensor coupledwith the photovoltaic facility may also be used to measure vapors and/orgases at chemical spill sites, in laboratories, or in the engine room orcompartment of a vehicle.

FIG. 103 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments a sensor may detectthe presence, absence, and/or one or more characteristics of a signal10302. Such a sensor may be associated with a photovoltaic facilitywhich may directly or indirectly act as an energy source for such asensor in any of the various configurations described throughout thisdisclosure. The signal may be any signal from another sensor, a cablesignal, a phone signal, a satellite signal, a telecommunications signal,a voice signal, an analog signal, a digital signal, an electricalsignal, and a mechanical signal. The sensor may react to the signal. Forexample, the sensor may cause a device powered by the photovoltaicfacility to turn on or off, or enter into standby mode, based on thesignal it receives. This functionality may result in decreased powerconsumption by the device. In addition, the sensor may respond tosignals from a network of sensors, reacting only when a variety ofconditions are met simultaneously or in a particular sequence.

FIG. 104 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments a signal sensor maydetect the presence, absence, and/or one or more characteristics of awireless signal 10402. A signal sensor may be used to detect signals forwireless protocols such as IEEE 802.11, jNetX, Bluetooth, Blackberry,TracerPlus, or other wireless communication protocol. Devices using asignal sensor may be wireless network routers, PDAs, Pocket PCs, cellphones, two-way communication devices, cell phone earbuds, or otherdevices that communicate wirelessly. The signal may be from any signalsource capable of broadcasting a signal. The signal sensor may react toa detected signal to enable/disable the device or enter a device sleepmode.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of a device, forexample a wireless network router, a PDA, a Pocket PC, a cell phone, atwo-way communication device, or a cell phone earbud. In embodiments,these devices may use an attachment (e.g. key chain); this attachmentmay have a photovoltaic skin, film, or flexible material applied to it,and the photovoltaic may provide power to the device. Alternatively, aphotovoltaic may charge a re-charger for the device, where there-charger has an interface to receive power from the photovoltaicfacility and a charging interface for the device. The device may includean energy storage capacity, such as a rechargeable battery.

FIG. 105 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, an internet signalsensor 10502 may detect a signal for wired or wireless communicationmethods. The sensor may be used to detect bandwidth, encryption type,security information, network accessed, or other information provided bythe connecting internet protocol. Devices that may use an internetsignal sensor may be a network router, computer network interface card(NIC), network switches, network hubs, cell phones, PDAs, Pocket PCs, orother devices capable of communication with the internet. The internetsignal sensor may react to a detected signal by enabling or disablingvarious interfaces. For example, a low speed connection may be detectedand the appropriate network protocol activated for communication.Another example is that, if the connection is of poor quality, theinternet sensor may slow down the communication rate to provide foracceptable communication.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of a device, forexample a network router, a computer network interface card (NIC), anetwork switch, a network hub, a cell phone, a PDA, and a Pocket PC.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, these devices may have photovoltaic cellsdisposed on deployable units that may provide the required amount ofpower for the electronic sensor. The deployable units may unfold, fanout, be stacked in an offset pattern, be positioned on a flat surface,or may be angled to take advantage of a light source. The deployablephotovoltaic facilities may be able to adjust the surface of unitsexposed to a light source manually or automatically. The photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the electronic sensor.

FIG. 106 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, sensors may providefeedback if detecting a touch or contact with another object. Inembodiments, touch/contact sensors 10602 may detect if the contact hasmade or removed from another object and may open or close an electricalcircuit.

In embodiments, touch sensors may be used in devices such as industrialpanels, appliance controls, light switches, elevator buttons, robotics,or other devices for detecting a touch. For example, an appliance mayhave time set by pressing a set of touch buttons on a panel.

In embodiments, contact sensors may be used in devices such as controlpanels, security systems, or other devices that detect whether objectsare in contact. For example, a network administrator may want theinformation if a control panel door has been opened. As another example,security systems may have sensors to detect when a window or door hasbeen opened.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of a device, forexample industrial panels, appliance controls, light switches, elevatorbuttons, or robotics. In embodiments, industrial or appliance controlsmay have the photovoltaic on the face of the touch panel itself.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, the devices listed above may have photovoltaiccells disposed on deployable units that may provide the required amountof power for the electronic sensor. The deployable units may unfold, fanout, be stacked in an offset pattern, be positioned on a flat surface,or may be angled to take advantage of a light source. The deployablephotovoltaic facilities may be able to adjust the surface of unitsexposed to a light source manually or automatically. The photovoltaicfacilities may be capable of automatically tracking a light source tomaintain the required power to the electronic sensor.

FIG. 107 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, viscosity sensors10702 may provide feedback of the properties of a fluid. Viscosity isthe measurement of the ability of a fluid to flow and then provide aconstant resistance. In embodiments, viscosity applies to all fluidssuch as oil, gas, water, body fluids, fluid mixtures, or other fluids.In embodiments, viscosity sensors may be used in devices such as medicaldevices for processing/testing blood, oil pipelines, oil/gas refineries,photographic fluid controls, manufacturing fluid controls, or otherdevices that measure and control fluid flow. In embodiments, theviscosity sensor may indicate that a fluid viscosity is out of anacceptable range and signal a control or display for action to be taken.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of these devices.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, the devices listed above may have photovoltaiccells disposed on deployable units that may provide the required amountof power for the sensor. The deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. The deployable photovoltaicfacilities may be able to adjust the surface of units exposed to a lightsource manually or automatically. The photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the sensor.

FIG. 108 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, a position sensor10802 may determine the position of an object by the strength of amagnetic field or by communication with a GPS broadcasting device. Inembodiments position sensors may provide compass heading,longitude/latitude, position on a map, or other positioning display. Inembodiments, position sensors may be used in automobiles, GPS devices,PDA devices, Pocket PCs, boats, aircraft, rockets, or other devices forpositioning an object. For example, an automobile may have a GPS deviceto display the position of the automobile in relation to a map.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of these devices.In embodiments, an automobile may have the photovoltaic applied to aninterior (e.g. dashboard) or exterior (hood, roof, trunk). Inembodiments, aircraft, boats and rockets may have the photovoltaicapplied to the skin of the vehicle. Alternatively, a photovoltaic maycharge a re-charger for the device, where the re-charger has aninterface to receive power from the photovoltaic facility and a charginginterface for the device. The device may include an energy storagecapacity, such as a rechargeable battery. In embodiments, the deviceslisted above may have photovoltaic cells disposed on deployable unitsthat may provide the required amount of power for the sensor. Thedeployable units may unfold, fan out, be stacked in an offset pattern,be positioned on a flat surface, or may be angled to take advantage of alight source. The deployable photovoltaic facilities may be able toadjust the surface of units exposed to a light source manually orautomatically. The photovoltaic facilities may be capable ofautomatically tracking a light source to maintain the required power tothe sensor.

FIG. 109 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, height sensors10902 may measure the vertical motion of an object in relation to a setposition. In embodiments, height sensors may be used to measuremachinery motions (e.g. grinding, drilling, milling, turning), waveheight measurements, atmospheric height measurements, or other objectsrequiring height measurements. In embodiments, devices that may useheight sensors are machinery scales, wave buoys, aircraft, or otherheight devices. In embodiments, height sensors may providedigital/analog feedback to a controller, computer, network of computers,or other device for display/calculations.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of these devices.In embodiments, aircraft may have the photovoltaic applied to the skinof the vehicle. Alternatively, a photovoltaic may charge a re-chargerfor the device, where the re-charger has an interface to receive powerfrom the photovoltaic facility and a charging interface for the device.The device may include an energy storage capacity, such as arechargeable battery. In embodiments, the devices listed above may havephotovoltaic cells disposed on deployable units that may provide therequired amount of power for the sensor. The deployable units mayunfold, fan out, be stacked in an offset pattern, be positioned on aflat surface, or may be angled to take advantage of a light source. Thedeployable photovoltaic facilities may be able to adjust the surface ofunits exposed to a light source manually or automatically. Thephotovoltaic facilities may be capable of automatically tracking a lightsource to maintain the required power to the sensor.

FIG. 110 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, ray sensors 11002(e.g. gamma or X-ray) may detect energy such as photons that may travelin a space. In embodiments, gamma rays or X-rays may originate from manmade or natural sources. In embodiments, gamma rays/X-rays may be usedin devices such as medical X-ray, mammography, radiology, X-rayfluorescence, archeology dating, nuclear plant monitoring,uranium/plutonium detection, or other similar devices. In embodiments,gamma ray/X-ray sensors may provide the level of gamma or X raysreceived from a source and provide this information to a controller,computer, or computer network.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of these devices.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, the devices listed above may have photovoltaiccells disposed on deployable units that may provide the required amountof power for the sensor. The deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. The deployable photovoltaicfacilities may be able to adjust the surface of units exposed to a lightsource manually or automatically. The photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the sensor.

FIG. 111 illustrates a photovoltaic sensor assembly according to theprinciples of the present invention. In embodiments, microwave sensors11102 may detect microwaves from another source or a reflected microwavefrom an object. In embodiments, microwaves may be broadcast, andreflected microwaves may be analyzed for the presence of objects in thebroadcast area. In embodiments, a microwave sensor may be able to detectif a microwave has been transmitted to the sensor or in the area of thesensor. In embodiments, devices that may use microwaves may be crosswalkpedestrian detectors, automatic doors, radar detectors, microwavetransmitter detectors, or other devices to detect microwaves. Inembodiments, a microwave sensor may provide a feedback to a controlleror computer that activates another device.

In embodiments, photovoltaic cells may be disposed as a skin, film, orflexible material that may be applied to the structure of these devices.Alternatively, a photovoltaic may charge a re-charger for the device,where the re-charger has an interface to receive power from thephotovoltaic facility and a charging interface for the device. Thedevice may include an energy storage capacity, such as a rechargeablebattery. In embodiments, the devices listed above may have photovoltaiccells disposed on deployable units that may provide the required amountof power for the sensor. The deployable units may unfold, fan out, bestacked in an offset pattern, be positioned on a flat surface, or may beangled to take advantage of a light source. The deployable photovoltaicfacilities may be able to adjust the surface of units exposed to a lightsource manually or automatically. The photovoltaic facilities may becapable of automatically tracking a light source to maintain therequired power to the sensor.

In embodiments, other sensors may be adapted to be associated withphotovoltaic such as an ultraviolet sensor, an infrared sensor, aproximity sensor, a distance sensor, a range sensor, a motion sensor, amote, a marker, a powered marker, a signal emitter, a powered signalemitter, a signal receiver, a powered signal receiver, a chemicalsensor, a hazardous material sensor, a hazardous vapor sensor, abiohazard sensor, a bacteria sensor, a virus sensor, an anthraxdetector, a nerve gas sensor, a poisonous gas sensor, a carbon monoxidedetector, a light sensor, an energy sensor, or other sensor.

Embodiments of the present invention relate to environments wherephotovoltaic sensor facilities according to the principles of thepresent invention may be deployed. For example, FIG. 112 illustratessuch systems in a home environment 11202. In embodiments, thephotovoltaic sensor may be used to provide detection of various events(e.g. those conditions illustrated herein, such as gas, smoke, entry,exit, waste, spills, structural events, timing, or other sensedconditions). FIG. 113 illustrates such systems in a government facilitysetting 11302. In embodiments, the photovoltaic sensor facility may beused in a government facility to sense conditions as described herein.FIG. 114 illustrates such systems in an office facility setting 11402.In embodiments, the photovoltaic sensor facility may be used in anoffice facility to sense conditions as described herein. FIG. 115illustrates such systems in a hospital setting 11502. In embodiments,the photovoltaic sensor facility may be used in a hospital facility tosense conditions as described herein. FIG. 116 illustrates such systemsin an industrial setting. In embodiments, the photovoltaic sensorfacility may be used in an industrial setting 11602 to sense conditionsas described herein. FIG. 117 illustrates such systems in a storagefacility setting 11702. In embodiments, the photovoltaic sensor facilitymay be used in a storage facility to sense conditions as describedherein. FIG. 118 illustrates such systems in a hazard reclamationsetting 11802. In embodiments, the photovoltaic sensor facility may beused in a hazard reclamation setting to sense conditions as describedherein. FIG. 119 illustrates such systems in a garage setting 11902. Inembodiments, the photovoltaic sensor facility may be used in a garagesetting to sense conditions as described herein. FIG. 120 illustratessuch systems in a station setting 12002. In embodiments, thephotovoltaic sensor facility may be used in a station setting to senseconditions as described herein.

In embodiments, the photovoltaic systems described herein may becombined and offered as a kit. The kit may be offered for sale in achannel appropriate for the applications and environments (e.g. a homephotovoltaic sensor facility offered for sale through commercial andconsumer market channels).

While the invention has been described in connection with certainpreferred embodiments, it should be understood that other embodimentswould be recognized by one of ordinary skill in the art, and areincorporated by reference herein.

1. A method, comprising: providing a sensor in association with aphotovoltaic facility to form a sensor-pv facility; and providing thesensor-pv facility in a kit adapted for purchase by a consumer to bedeployed in a home environment.
 2. The method of claim 1 furthercomprising providing an energy storage facility for storing energygenerated by the photovoltaic facility.
 3. The method of claim 1 furthercomprising providing a feedback loop from the sensor to control thesensor-pv facility.
 4. The method of claim 1 wherein the sensorcomprises a smoke detector.
 5. The method of claim 1 wherein the sensorcomprises a fire detector.
 6. The method of claim 1 wherein the sensorcomprises a hazard detector.
 7. The method of claim 1 wherein the sensorcomprises a hazardous waste detector.
 8. The method of claim 1 whereinthe sensor comprises a gas detector.
 9. The method of claim 1 whereinthe sensor comprises a mechanical sensor.
 10. The method of claim 1wherein the sensor comprises an electrical sensor.
 11. The method ofclaim 1 wherein the sensor comprises a biological sensor.
 12. The methodof claim 1 wherein the sensor comprises a chemical sensor.
 13. Themethod of claim 1 wherein the sensor comprises an optical sensor. 14.The method of claim 1 wherein the sensor is an ozone sensor.
 15. Themethod of claim 1 wherein the sensor is a carbon monoxide sensor. 16.The method of claim 1 wherein the sensor is a lead sensor.
 17. Themethod of claim 1 wherein the sensor is an asbestos sensor.
 18. Themethod of claim 1 wherein the sensor detects mold.
 19. The method ofclaim 1 wherein the sensor detects bacteria.
 20. The method of claim 1wherein the sensor is a temperature sensor.
 21. The method of claim 1wherein the photovoltaic facility is flexible.
 22. The method of claim21 wherein the photovoltaic facility is foldable.
 23. The method ofclaim 21 wherein the photovoltaic facility is rotatable.
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 45. A system, comprising: a sensor inassociation with a photovoltaic facility to form a sensor-pv facility;and a kit adapted for purchase by a consumer including the sensor-pvfacility adapted to be deployed in a home environment.
 46. The system ofclaim 45 further comprising an energy storage facility in associationwith the sensor-pv facility for storing energy generated by thephotovoltaic facility.
 47. The system of claim 45 further comprising afeedback loop from the sensor to control the sensor-pv facility.
 48. Thesystem of claim 45 wherein the sensor comprises a smoke detector. 49.The system of claim 45 wherein the sensor comprises a fire detector. 50.The system of claim 45 wherein the sensor comprises a hazard detector.51. The system of claim 45 wherein the sensor comprises a hazardouswaste detector.
 52. The system of claim 45 wherein the sensor comprisesa gas detector.
 53. The system of claim 45 wherein the sensor comprisesa mechanical sensor.
 54. The system of claim 45 wherein the sensorcomprises an electrical sensor.
 55. The system of claim 45 wherein thesensor comprises a biological sensor.
 56. The system of claim 45 whereinthe sensor comprises a chemical sensor.
 57. The system of claim 45wherein the sensor comprises an optical sensor.
 58. The system of claim45 wherein the sensor is an ozone sensor.
 59. The system of claim 45wherein the sensor is a carbon monoxide sensor.
 60. The system of claim45 wherein the sensor is a lead sensor.
 61. The system of claim 45wherein the sensor is an asbestos sensor.
 62. The system of claim 45wherein the sensor detects mold.
 63. The system of claim 45 wherein thesensor detects bacteria.
 64. The system of claim 45 wherein the sensoris a temperature sensor.
 65. The system of claim 45 wherein thephotovoltaic facility is flexible.
 66. The system of claim 65 whereinthe photovoltaic facility is foldable.
 67. The system of claim 65wherein the photovoltaic facility is rotatable.
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